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31-05-2020 | Review Paper

Fog computing in health: A systematic literature review

Authors: Humberto Jorge de Moura Costa, Cristiano André da Costa, Rodrigo da Rosa Righi, Rodolfo Stoffel Antunes

Published in: Health and Technology | Issue 5/2020

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Abstract

Currently, technology greatly benefits the area of healthcare. Modern computers can quickly process a large volume of patient health records. Due to recent advances in the area of Internet of Things and healthcare, patient data can be dispersed in multiple locations. As a result, scientists have been proposing solutions based on Cloud Computing to manage healthcare data. However, suchs solutions present challenges regarding access latency, context-awareness, and large volumes of data. There is an increased probability of processing and transmission errors are more likely to occur as health data sets become larger and more complex. In this context, Fog Computing presents itself as an alternative to reduce health data management complexity, consequently increasing its reliability. To that end, it is important to comprehend the associated challenges before defining a Fog Computing-based architecture to manage healthcare data. This article presents a systematic literature review of fog computing being applied to healthcare area. We propose a taxonomy to explore the open issues and most important challenges on these fields of study. We selected 1070 scientific articles published in the last 10 years, filtering the 44 most significant works for an in-depth analysis. We found that there is several challenges to be addressed such as interoperability, privacy, security, data processing, management of resources and Big Data issues. Also, our contribution include developing a taxonomy for the Fog Computing and healthcare fields of study and finding out challenges and open questions of this area.

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de Morais Barroca Filho I, de Aquino Junior GS. 2017. Iot-based healthcare applications: A review. In: International conference on computational science and its applications, pp 47–62. Springer.

Alam GR Md, Munir S Md, Uddin Z Md, Alam MS, Dang TN, Hong CS. Edge-of-things computing framework for cost-effective provisioning of healthcare data. J Parallel Distr Comput 2019;123:54–60.CrossRef

Verma P, Sood SK. Cloud-centric iot based disease diagnosis healthcare framework. J Parallel Distr Comput 2018;116:27– 38.CrossRef

Gia TN, Jiang M, Rahmani A-M, Westerlund T, Liljeberg P, Tenhunen H. 2015. Fog computing in healthcare internet of things: A case study on ecg feature extraction. In: 2015 IEEE international conference on Computer and information technology; ubiquitous computing and communications; dependable, autonomic and secure computing; pervasive intelligence and computing (CIT/IUCC/DASC/PICOM), pp 356–363. IEEE.

Mell P, Grance T, et al. The nist definition of cloud computing. Commun ACM 2011;53(6):50.

Kraemer FA, Braten AE, Tamkittikhun N, Palma D. Fog computing in healthcare–a review and discussion. IEEE Access 2017;5:9206–9222.CrossRef

da Costa CA, Pasluosta CF, Eskofier B, da Silva DB, da Rosa Righi R. Internet of health things: Toward intelligent vital signs monitoring in hospital wards. Artif Intell Med 2018;89:61–69.CrossRef

Yangui S, Glitho RH, Morrow MJ, Mouradian C, Naboulsi D, Polakos PA. A comprehensive survey on fog computing: State-of-the-art and research challenges. IEEE Commun Surv Tutorials 2017;3:854–864.

Gia TN, Rahmani AM, Westerlund T, Liljeberg P, Tenhunen H. Fog computing approach for mobility support in internet-of-things systems. IEEE Access 2018;6:36064–36082.CrossRef

10.

Zhu J, Bonomi F, Milito R, Addepalli PLS, Tenhunen H. 2012. Fog computing and its role in the internet of things. In: MCC workshop mobile cloud comput., pp 13–16. New York.

11.

Mokhtari G, Anvari-Moghaddam A, Zhang Q. 2019. A new layered architecture for future big data-driven smart homes. IEEE Access.

12.

Andriopoulou F, Dagiuklas T, Orphanoudakis T. Integrating iot and fog computing for healthcare service delivery. Components and services for iot platforms: Paving the way for iot standards. Cham: Springer International Publishing; 2017. p. 213–32.

13.

Mieronkoski R, Azimi I, Rahmani AM, Aantaa R, Terävä V, Liljeberg P, Salanterä S. The internet of things for basic nursing care — a scoping review. Int J Nursing Stud 2017;69:78–90.CrossRef

14.

Buyya R, Yeo CS, Venugopal S, Broberg J, Brandic I. Cloud computing and emerging it platforms: Vision, hype, and reality for delivering computing as the 5th utility. Future Gener Comput Syst 2009;25(6):599–616.CrossRef

15.

Vaquero LM, Rodero-Merino L. Finding your way in the fog: Towards a comprehensive definition of fog computing. SIGCOMM Comput Commun Rev 2014;44(5):27–32.CrossRef

16.

Iorga M, Feldman L, Barton R, Martin MJ, Goren NS, Mahmoudi C. 2018. Fog computing conceptual model. Technical report NIST.

17.

Kumari A, Tanwar S, Tyagi S, Kumar N. Fog computing for healthcare 4.0 environment: Opportunities and challenges. Comput Elect Eng 2018;72:1–13.CrossRef

18.

Farahani B, Firouzi F, Chang V, Badaroglu M, Constant N, Mankodiya K. Towards fog-driven iot ehealth: Promises and challenges of iot in medicine and healthcare. Futur Gener Comput Syst 2018;78:659–676.CrossRef

19.

Hu P, Dhelim S, Ning H, Qiu T. Survey on fog computing: Architecture, key technologies, applications and open issues. J Netw Comput Appl 2017;98:27–42.CrossRef

20.

Chakraborty S, Bhowmick S, Talaga P, Agrawal DP. 2016. Fog networks in healthcare application. In: IEEE 13th international conference on mobile ad hoc and sensor systems (MASS), pp 386–387. IEEE.

21.

Budgen D, Brereton P. 2006. Performing systematic literature reviews in software engineering. In: Proceedings of the 28th international conference on Software engineering, pp 1051–1052. ACM.

22.

Biolchini J, Mian PG, Cruz NAC, Travassos GH. Systematic review in software engineering system engineering and computer science department COPPE/UFRJ. Technical Report ES 2005;679(05):45.

23.

Kitchenham B. 2004. Procedure for undertaking systematic reviews. Computer Science Department, Keele University (TRISE-0401) and National ICT Australia Ltd Joint Technical Report.

24.

Kitchenham B. 2007. Guidelines for performing systematic literature reviews in software engineering.

25.

Roberts H, Petticrew M. 2006. Systematic reviews in the social sciences. Blackwell Pub;.

26.

Sood SK, Mahajan I. A fog-based healthcare framework for chikungunya. IEEE Internet Things J 2018;5 (2):794–801.CrossRef

27.

Manogaran G, Varatharajan R, Lopez D, Kumar PM, Sundarasekar R, Thota C. A new architecture of internet of things and big data ecosystem for secured smart healthcare monitoring and alerting system. Futur Gener Comput Syst 2018;82:375–387.CrossRef

28.

Verma P, Sood SK. Cloud-centric iot based disease diagnosis healthcare framework. J Parallel Distr Comput 2018;116:27–38.CrossRef

29.

Rahmani A M, Gia TN, Negash B, Anzanpour A, Azimi I, Jiang M, Liljeberg P. Exploiting smart e-health gateways at the edge of healthcare internet-of-things: A fog computing approach. Futur Gener Comput Syst 2018;78:641–658.CrossRef

30.

Bhatia M, Sood SK. 2018. Exploring temporal analytics in fog-cloud architecture for smart office healthcare. Mobile Networks and Applications, 1–19.

31.

Verma P, Sood SK. 2018. Fog assisted-iot enabled patient health monitoring in smart homes. IEEE Internet of Things Journal.

32.

Klonoff DC. Fog computing and edge computing architectures for processing data from diabetes devices connected to the medical internet of things. J Diabetes Sci Technol 2017;11(4):647– 652.CrossRef

33.

Moore P, Van Pham H. 2018. Fog computing and low latency context-aware health monitoring in smart interconnected environments. In: International conference on emerging internetworking, data & web technologies, pp 29–40. Springer.

34.

Sood SK, Mahajan I. 2018. Fog-cloud based cyber-physical system for distinguishing, detecting and preventing mosquito borne diseases. Future Generation Computer Systems.

35.

Liu X, Deng R H, Yang Y, Tran HN, Zhong S. Hybrid privacy-preserving clinical decision support system in fog–cloud computing. Futur Gener Comput Syst 2018;78:825–837.CrossRef

36.

Barik RK, Dubey H, Mankodiya K, Sasane SA, Misra C. Geofog4health: A fog-based sdi framework for geospatial health big data analysis. J Ambient Intell Humaniz Comput 2019;10:551–567.CrossRef

37.

Maksimović M. 2018. Hybrid privacy-preserving clinical decision support system in fog–cloud computing. ITA-JOURNAL OF INFORMATION TECHNOLOGY AND APLICATIONS, 14(2).

38.

Barik RK, Dubey AC, Tripathi A, Pratik T, Sasane S, Lenka RK, Dubey H, Mankodiya K, Kumar Vinay. Mist data: Leveraging mist computing for secure and scalable architecture for smart and connected health. Proc Comput Sci 2018;125:647–653.CrossRef

39.

Masouros D, Bakolas I, Tsoutsouras V, Siozios K, Soudris D. 2017. From edge to cloud: Design and implementation of a healthcare internet of things infrastructure. In: 2017 27th international symposium on power and timing modeling, optimization and simulation (PATMOS), pp 1–6. IEEE.

40.

Cerina L, Notargiacomo S, Paccanit MGL, Santambrogio MD. 2017. A fog-computing architecture for preventive healthcare and assisted living in smart ambients. In: 2017 IEEE 3rd international forum on research and technologies for society and industry (RTSI), pp 1–6. IEEE.

41.

Elmisery AM, Rho S, Aborizka M. A new computing environment for collective privacy protection from constrained healthcare devices to iot cloud services. Clust Comput 2017;22:1–28.

42.

Abdulaziz H, Al Hamid SK Md, Rahman M, Shamim Hossain M, Almogren A, Alamri A. A security model for preserving the privacy of medical big data in a healthcare cloud using a fog computing facility with pairing-based cryptography. IEEE Access 2017;5:22313–22328.CrossRef

43.

Nastic S, Rausch T, Scekic O, Dustdar S, Gusev M, Koteska B, Kostoska M, Jakimovski B, Ristov S, Prodan R. A serverless real-time data analytics platform for edge computing. IEEE Internet Comput 2017;21(4):64–71.CrossRef

44.

Kharel J, Reda HT , Shin SY. 2017. An architecture for smart health monitoring system based. Journal of Communications, 12(4).

45.

Sareen S, Gupta SK, Sood SK. An intelligent and secure system for predicting and preventing zika virus outbreak using fog computing. Enterprise Inf Syst 2017;11(9):1436– 1456.

46.

Ungurean I, Brezulianu A. An internet of things framework for remote monitoring of the healthcare parameters. Adv Elect Comput Eng 2017;17(2):11–16.CrossRef

47.

Ul Abideen Z, Shah MA. 2017. An iot based robust healthcare model for continuous health monitoring. In: 2017 23rd international conference on automation and computing (ICAC), pp 1–6. IEEE.

48.

Alshiky AM, Buhari SM, Barnawi A. 2017. Ehr attribute-based access control (abac) for fog computing environment. Computer Science & Information Technology, page 87.

49.

Markakis EK, Lykourgiotis A, Politis I, Dagiuklas A, Rebahi Y, Pallis E. Emynos: Next generation emergency communication. IEEE Commun Mag 2017;55(1):139–145.CrossRef

50.

Kharel J, Reda HT, Shin SY. Fog computing-based smart health monitoring system deploying lora wireless communication. IETE Tech Rev 2017;36:1–14.

51.

Azimi I, Anzanpour A, Rahmani AM, Pahikkala T, Levorato M, Liljeberg P, Dutt N. Hich: Hierarchical fog-assisted computing architecture for healthcare iot. ACM Trans Embedded Comput Syst (TECS) 2017;16(5s):174.

52.

Gia TN, Jiang M, Sarker VK, Rahmani AM, Westerlund T, Liljeberg P, Tenhunen H. 2017. Low-cost fog-assisted health-care iot system with energy-efficient sensor nodes. In: 2017 13th international wireless communications and mobile computing conference (IWCMC), pp 1765–1770. IEEE.

53.

Akrivopoulos O, Chatzigiannakis I, Tselios C, Antoniou A. 2017. On the deployment of healthcare applications over fog computing infrastructure. In: 2017 IEEE 41st annual computer software and applications conference (COMPSAC), vol. 2, pp 288–293. IEEE.

54.

He S, Bo C, Wang H, Huang Y, Chen J. Proactive personalized services through fog-cloud computing in large-scale iot-based healthcare application. China Commun 2017;14(11):1–16.CrossRef

55.

Ali S, Ghazal M. 2017. Real-time heart attack mobile detection service (rhamds): An iot use case for software defined networks. In: 2017 IEEE 30th Canadian conference on electrical and computer engineering (CCECE), pp 1–6. IEEE.

56.

Sood SK, Mahajan I. Wearable iot sensor based healthcare system for identifying and controlling chikungunya virus. Comput Ind 2017;91:33–44.CrossRef

57.

Canonico MSM, Montani S. A telemedicine support for improving medical emergency management. EAI Endorsed Trans Ambient Syst 2017;4(16):1–6.

58.

Zamfir M, Florian V, Stanciu A, Neagu G, Preda Ş, Militaru G. 2016. Towards a platform for prototyping iot health monitoring services. In: International conference on exploring services science, pp 522–533. Springer.

59.

Khalid A, Shahbaz M, Fayyaz H. Using body sensor networks to show that fog computing is more efficient than traditional cloud computing. Int J Comput Sci Inf Secur 2016;14(12):190.

60.

González LP, Jaedicke C, Schubert J, Stantchev V. Fog computing architectures for healthcare: Wireless performance and semantic opportunities. Journal of Information. Commun Ethics Soc 2016;14(4):334–349.CrossRef

61.

Ahmad M, Amin MB, Hussain S, Kang BH, Cheong T, Lee S. Health fog: A novel framework for health and wellness applications. J Supercomput 2016;72(10):3677–3695.CrossRef

62.

Azimi I, Anzanpour A, Rahmani AM, Liljeberg P, Salakoski T. 2016. Medical warning system based on internet of things using fog computing. In: International workshop on big data and information security (IWBIS), pp 19–24. IEEE.

63.

Ramalho F, Neto A, Santos K, Agoulmine N, et al. 2015. Enhancing ehealth smart applications: A fog-enabled approach. In: 2015 17th international conference on E-health networking, application & services (HealthCom), pages 323–328. IEEE.

64.

Yu C, Hou P, Brown D, Wang J, Chen S. 2015. Distributed analytics and edge intelligence: Pervasive health monitoring at the era of fog computing. In: Proceedings of the 2015 workshop on mobile big data, pp 43–48. ACM.

65.

Fratu O, Pena C, Craciunescu R, Halunga S. 2015. Fog computing system for monitoring mild dementia and copd patients-romanian case study. In: 2015 12th international conference on telecommunication in modern satellite, Cable and Broadcasting Services (TELSIKS), pp 123–128. IEEE.

66.

Dubey H, Yang J, Constant N, Amiri AM, Yang Q, Makodiya K. 2015. Fog data: Enhancing telehealth big data through fog computing. In: Proceedings of the ASE bigdata & socialinformatics 2015, pp 14. ACM.

67.

Stantchev V, Barnawi A, Ghulam S, Schubert J, Tamm G. Smart items, fog and cloud computing as enablers of servitization in healthcare. Sensors & Transducers 2015;185(2):121.

68.

Bondi AB. 2000. Characteristics of scalability and their impact on performance. In: Proceedings of the 2nd international workshop on Software and performance, pages 195–203 ACM.

69.

Lewis G. 2013. Role of standards in cloud-computing interoperability. In: 2013 46th Hawaii international conference on system sciences, pp 1652–1661. IEEE.

70.

Oliveira RN, Roth V, Henzen AF, Simao JM, Nohama P, Gomes WEC. Notification oriented paradigm applied to ambient assisted living tool. IEEE Lat Am Trans 2018;16(2):647– 653.CrossRef

Title: Fog computing in health: A systematic literature review
Authors: Humberto Jorge de Moura Costa
Cristiano André da Costa
Rodrigo da Rosa Righi
Rodolfo Stoffel Antunes
Publication date: 31-05-2020
Publisher: Springer Berlin Heidelberg
Published in: Health and Technology / Issue 5/2020
Print ISSN: 2190-7188
Electronic ISSN: 2190-7196
DOI: https://doi.org/10.1007/s12553-020-00431-8

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