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Wireless Personal Communications
Published in: Wireless Personal Communications 1/2023

21-03-2023

A Review: Security and Privacy for Health Care Application in Wireless Body Area Networks

Authors: V. D. Gaikwad, S. Ananthakumaran

Published in: Wireless Personal Communications | Issue 1/2023

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Abstract

At present, the utilization of wireless sensor networks (WSN) is extended into various sectors such as military, building monitoring, health monitoring, surveillance, industrial process security, control and monitoring and habitat monitoring. Among these, the implementation of WSN has occurred in health monitoring as body sensor networks (BSNs) which lead to a signification change in the everyday life of people. The major advantage of BSN is consistent physiological monitoring of humans, in which humans have not suffered from any unnecessary noises. Because of the BSNs assisted monitoring, some benefits such as prevention of disease or activity analysis for detection, integration of BSN data with the environment data and rehabilitation after a medical procedure has occurred. Recently several works have been done to maintain and improve the ageing world population from chronic diseases. This review mainly focuses on security and privacy for healthcare applications in wireless body area networks (WBANs). BAN technology establishes a method that monitors the patient’s health status in or around the human body by tiny wireless sensor devices which support medical professionals. However, it faces some difficulties in implementing and designing, like security and privacy for everybody since it holds information. Data should keep data consistency, power failure, high secrecy, validation of sensor versus system compatibility and so on. Furthermore, the review conveys the best way to maintain and improve the dependability of WBAN.
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Literature
1.
Cicioğlu, M., & Çalhan, A. (2020). Channel aware wireless body area network with cognitive radio technology in disaster cases. International Journal of Communication Systems, 33, e4565.
2.
Yaghoubi, M., Ahmed, K., & Miao, Y. (2022). Wireless body area network (WBAN): A survey on architecture, technologies, energy consumption, and security challenges. Journal of Sensor and Actuator Networks, 11(4), 67.CrossRef
3.
Sodhro, A. H., et al. (2019). Mobile edge computing based QoS optimization in medical healthcare applications. International Journal of Information Management, 45, 308–318.CrossRef
4.
Muzammal, M., et al. (2020). A multi-sensor data fusion enabled ensemble approach for medical data from body sensor networks. Information Fusion, 53, 155–164.CrossRef
5.
Sodhro, A. H. (2019). Medical quality of service optimization over joint body sensor networks and internet of multimedia things. In Advances in body area networks I (pp. 205–220). Cham: Springer.
6.
Zhao, H., et al. (2019). Adaptive gait detection based on foot-mounted inertial sensors and multi-sensor fusion. Information Fusion, 52, 157–166.CrossRef
7.
Mahima, V., & Chitra, A. (2019). A novel energy harvesting: cluster head rotation scheme (EH-CHRS) for green wireless sensor network (GWSN). Wireless Personal Communications, 107, 1–15.
8.
Cheng, Q., Li, Y., Shi, W., & Li, X. (2022). A certificateless authentication and key agreement scheme for secure cloud-assisted wireless body area network. Mobile Networks and Applications, 27(1), 346–356.MathSciNetCrossRef
9.
Ghamari, M., Janko, B., Sherratt, R. S., Harwin, W., Piechockic, R., & Soltanpur, C. (2016). A survey on wireless body area networks for ehealthcare systems in residential environments. Sensors (Basel, Switzerland), 16(6), 831.CrossRef
10.
Sodagari, S., Bozorgchami, B., & Aghvami, H. (2018). Technologies and challenges for cognitive radio enabled medical wireless body area networks. IEEE Access: Practical Innovations, Open Solutions, 6, 29567–29586.CrossRef
11.
Beg, S., Handa, M., Shukla, R., Rahman, M., Almalki, W. H., Afzal, O., & Altamimi, A. S. A. (2022). Wearable smart devices in cancer diagnosis and remote clinical trial monitoring: Transforming the healthcare applications. Drug Discovery Today.
12.
Pirbhulal, S., et al. (2019). A joint resource-aware and medical data security framework for wearable healthcare systems. Future Generation Computer Systems, 95, 382–391.CrossRef
13.
Sivasangari, A., Ananthi, A., Deepa, D., Rajesh, G., & Raajini, X. M. (2021). Security and privacy in wireless body sensor networks using lightweight cryptography scheme. In Security and privacy issues in IoT devices and sensor networks (pp. 43–59). Academic Press.
14.
Shakeel, P. M., Baskar, S., & Selvakumar, S. (2019). Retrieving multiple patient information by using the virtual MIMO and path beacon in wireless body area network. Wireless Personal Communications, 108, 1–12.
15.
Liu, X., et al. (2020). Adjusting forwarder nodes and duty cycle using packet aggregation routing for body sensor networks. Information Fusion, 53, 183–195.CrossRef
16.
Laurijssen, D., et al. (2019). Synchronous wireless body sensor network enabling human body pose estimation. IEEE Access: Practical Innovations, Open Solutions, 7, 49341–49351.CrossRef
17.
Shahid, J., Ahmad, R., Kiani, A. K., Ahmad, T., Saeed, S., & Almuhaideb, A. M. (2022). Data protection and privacy of the internet of healthcare things (IoHTs). Applied Sciences, 12(4), 1927.CrossRef
18.
Izza, S., Benssalah, M., & Drouiche, K. (2021). An enhanced scalable and secure RFID authentication protocol for WBAN within an IoT environment. Journal of Information Security and Applications, 58, 102705.CrossRef
19.
Bai, T., et al. (2019). An optimized protocol for QoS and energy efficiency on wireless body area networks. Peer-to-Peer Networking and Applications, 12(2), 326–336.CrossRef
20.
Hasan, K., Chowdhury, M. J. M., Biswas, K., Ahmed, K., Islam, M. S., & Usman, M. (2022). A blockchain-based secure data-sharing framework for software defined wireless body area networks. Computer Networks, 211, 109004.CrossRef
21.
Hussain, S. J., Irfan, M., Jhanjhi, N. Z., Hussain, K., & Humayun, M. (2021). Performance enhancement in wireless body area networks with secure communication. Wireless Personal Communications, 116(1), 1–22.CrossRef
22.
Lee, S., Shi, Q., & Lee, C. (2019). From flexible electronics technology in the era of IoT and artificial intelligence toward future implanted body sensor networks. APL Materials, 7(3), 031302.CrossRef
23.
Kadhim, K. T., Alsahlany, A. M., Wadi, S. M., & Kadhum, H. T. (2020). An overview of patient’s health status monitoring system based on internet of things (IoT). Wireless Personal Communications, 114(3), 2235–2262.CrossRef
24.
Akhbarifar, S., Javadi, H. H. S., Rahmani, A. M., & Hosseinzadeh, M. (2020). A secure remote health monitoring model for early disease diagnosis in cloud-based IoT environment. Personal and Ubiquitous Computing, 1–17.
25.
Vimal, S., Khari, M., Crespo, R. G., Kalaivani, L., Dey, N., & Kaliappan, M. (2020). Energy enhancement using Multiobjective ant colony optimization with double Q learning algorithm for IoT based cognitive radio networks. Computer Communications, 154, 481–490.CrossRef
26.
Himaja, C., Chowdar, Y. S., Amarendra, K., & Ananthakumaran, S. (2020). An effective method to secure electronic health record based on block chain technology. International Journal of Advanced Trends in Computer Science and Engineering, 9(2), 1628–1632.CrossRef
27.
Alzahrani, B. A., Irshad, A., Albeshri, A., & Alsubhi, K. (2021). A provably secure and lightweight patient-healthcare authentication protocol in wireless body area networks. Wireless Personal Communications, 117(1), 47–69.CrossRef
28.
Zhao, K., Sun, D., Ren, G., & Zhang, Y. (2020). Public auditing scheme with identity privacy preserving based on certificateless ring signature for wireless body area networks. IEEE Access: Practical Innovations, Open Solutions, 8, 41975–41984.CrossRef
29.
Jalili Marandi, S., Golsorkhtabaramiri, M., Hosseinzadeh, M., & Jassbi, S. J. (2022). IoT based thermal aware routing protocols in wireless body area networks: Survey: IoT based thermal aware routing in WBAN. IET Communications, 16(15), 1753–1771.CrossRef
30.
Bhatia, M., & Kumar, K. (2020). Network selection in cognitive radio enabled wireless body area networks. Digital Communications and Networks, 6(1), 75–85.CrossRef
31.
Ren, Y., et al. (2019). Data storage mechanism based on blockchain with privacy protection in Wireless Body Area Network. Sensors (Basel, Switzerland), 19(10), 2395.CrossRef
32.
Muthuvel, S., Rajagopal, S., & Subramaniam, S. K. (2022). Analysis of Security issues in Wireless Body Area Networks in Heterogeneous Networks. Sensors (Basel, Switzerland), 22(19), 7588.CrossRef
33.
Narwal, B., & Mohapatra, A. K. (2021). A survey on security and authentication in wireless body area networks. Journal of Systems Architecture, 113, 101883.CrossRef
34.
Bhatti, D. S., Saleem, S., Imran, A., Iqbal, Z., Alzahrani, A., Kim, H., & Kim, K. I. (2022). A Survey on Wireless Wearable Body Area Networks: a perspective of Technology and Economy. Sensors (Basel, Switzerland), 22(20), 7722.CrossRef
35.
Pragadeswaran, S., Madhumitha, S., & Gopinath, S. (2021). Certain investigation on military applications of Wireless Sensor Network. International Journal of Advanced Research in Science Communication and Technology, 3(1), 14–19.CrossRef
36.
Mohamed, M. B., Meddeb-Makhlouf, A., Fakhfakh, A., & Kanoun, O. (2022). Efficient data aggregation technique for medical wireless body sensor networks. tm-Technisches Messen, 89(5), 328–342.CrossRef
37.
Cao, Y., et al. (2018). Muscle activity-driven green-oriented random number generation mechanism to secure WBSN wearable device communications. Wireless Communications and Mobile Computing.
38.
Shanthapriya, R., & Vaithianathan, V. (2019). Secured healthcare monitoring system in wireless body area network using polynomial based technique. Polish Journal of Medical Physics and Engineering, 25(3), 171–177.CrossRef
39.
Hamici, Z. (2018). Towards genetic cryptography for Biomedical Wireless Sensor Networks Gateways. IEEE Journal of Biomedical and Health Informatics, 22(6), 1814–1823.CrossRef
40.
Hussain, S., Ullah, S. S., Uddin, M., Iqbal, J., & Chen, C. L. (2022). A comprehensive survey on signcryption security mechanisms in wireless body area networks. Sensors (Basel, Switzerland), 22(3), 1072.CrossRef
41.
Noor, F., Kordy, T. A., Alkhodre, A. B., Benrhouma, O., Nadeem, A., & Alzahrani, A. (2021). Securing Wireless Body Area Network with Efficient Secure Channel Free and Anonymous Certificateless Signcryption. Wireless Communications and Mobile Computing, 2021.
42.
Itani, W., Kayssi, A., & Chehab, A. (2019). Wireless Body Sensor Networks: Security, Privacy, and Energy Efficiency in the Era of Cloud Computing. In Cyber Law, Privacy, and Security: Concepts, Methodologies, Tools, and Applications, IGI Global, 731–763.
43.
Yi, X., et al. (2015). Privacy protection for wireless medical sensor data. IEEE transactions on dependable and secure computing, 13(3), 369–380.CrossRef
44.
Lin, C., et al. (2016). A differential privacy protection scheme for sensitive big data in body sensor networks. Annals of Telecommunications, 71(9–10), 465–475.CrossRef
45.
Shen, J., Gui, Z., Ji, S., Shen, J., Tan, H., & Tang, Y. (2018). Cloud-aided lightweight certificateless authentication protocol with anonymity for wireless body area networks. Journal of Network and Computer Applications, 106, 117–123.CrossRef
46.
Khan, F. H., et al. (2018). A secure Crypto Base Authentication and Communication suite in Wireless Body Area Network (WBAN) for IoT Applications. Wireless Personal Communications, 103(4), 2877–2890.CrossRef
47.
Challa, S., et al. (2018). An efficient ECC-based provably secure three-factor user authentication and key agreement protocol for wireless healthcare sensor networks. Computers & Electrical Engineering, 69, 534–554.CrossRef
48.
Wei, F., et al. (2018). A provably secure password-based anonymous authentication scheme for wireless body area networks. Computers & Electrical Engineering, 65, 322–331.CrossRef
49.
Pu, C., Zerkle, H., Wall, A., Lim, S., Choo, K. K. R., & Ahmed, I. (2022). A Lightweight and Anonymous Authentication and Key Agreement Protocol for Wireless Body Area Networks.IEEE Internet of Things Journal.
50.
Shen, J., Chang, S., Liu, Q., Shen, J., & Ren, Y. (2018). Implicit authentication protocol and self-healing key management for WBANs. Multimedia Tools and Applications, 77(9), 11381–11401.CrossRef
51.
Jiang, Q., Lian, X., Yang, C., Ma, J., Tian, Y., & Yang, Y. (2016). A bilinear pairing based anonymous authentication scheme in wireless body area networks for mHealth. Journal of medical systems, 40(11), 231.CrossRef
52.
Rangwani, D., & Om, H. (2022). Four-factor mutual authentication scheme for healthcare based on wireless body area network. The Journal of Supercomputing, 78(4), 5744–5778.CrossRef
53.
Wu, F., et al. (2017). An improved and anonymous two-factor authentication protocol for healthcare applications with wireless medical sensor networks. Multimedia Systems, 23(2), 195–205.CrossRef
54.
Lara, E., Aguilar, L., & García, J. A. (2021). Lightweight authentication protocol using self-certified public keys for wireless body area networks in healthcare applications. Ieee Access: Practical Innovations, Open Solutions, 9, 79196–79213.CrossRef
55.
Narwal, B., & Mohapatra, A. K. (2021). SAMAKA: Secure and anonymous mutual authentication and key agreement scheme for wireless body area networks. Arabian Journal for Science and Engineering, 46(9), 9197–9219.CrossRef
56.
Ibrahim, M. H., et al. (2016). Secure anonymous mutual authentication for star two-tier wireless body area networks. Computer Methods and Programs in Biomedicine, 135, 37–50.CrossRef
57.
Abiramy, N. V., & Sudha, S. V. (2019). A secure and lightweight authentication protocol for multiple layers in wireless body area network. In Smart intelligent computing and applications (Vol. 1, pp. 287–296). Singapore: Springer.
58.
Ostad-Sharif, A., Nikooghadam, M., & Abbasinezhad‐Mood, D. (2019). Design of a lightweight and anonymous authenticated key agreement protocol for wireless body area networks. International Journal of Communication Systems, 32(12), e3974.CrossRef
59.
Tan, H., & Chung, I. (2019). Secure authentication and group key distribution scheme for WBANs based on smartphone ECG sensor. IEEE Access: Practical Innovations, Open Solutions, 7, 151459–151474.CrossRef
60.
Wazid, M., Das, A. K., & Vasilakos, A. V. (2018). Authenticated key management protocol for cloud-assisted body area sensor networks. Journal of Network and Computer Applications, 123, 112–126.CrossRef
61.
Wang, C., Zheng, W., Ji, S., Liu, Q., & Wang, A. (2018). Identity-based fast authentication scheme for smart mobile devices in body area networks. Wireless Communications and Mobile Computing.
62.
Devi, V. A., & Kalaivani, V. (2021). Enhanced BB84 quantum cryptography protocol for secure communication in wireless body sensor networks for medical applications. Personal and Ubiquitous Computing, 1.
63.
Ullah, I., Zeadally, S., Amin, N. U., Khan, M. A., & Khattak, H. (2021). Lightweight and provable secure cross-domain access control scheme for internet of things (IoT) based wireless body area networks (WBAN). Microprocessors and Microsystems, 81, 103477.CrossRef
64.
Umar, M., Wu, Z., & Liao, X. (2021). Channel characteristics aware zero knowledge proof based authentication scheme in body area networks. Ad Hoc Networks, 112, 102374.CrossRef
65.
Tewari, A., & Verma, P. (2016). Security and privacy in E-healthcare monitoring with WBAN: A critical review. International Journal of Computer Applications, 136(11), 37–42.
66.
Azees, M., Vijayakumar, P., Karuppiah, M., & Nayyar, A. (2021). An efficient anonymous authentication and confidentiality preservation schemes for secure communications in wireless body area networks. Wireless Networks, 27(3), 2119–2130.CrossRef
67.
Mendez, D. M., Papapanagiotou, I., & Yang, B. (2017). Internet of things: Survey on security and privacy. arXiv preprint arXiv:​1707.​01879.
68.
Malik, M. S. A., Ahmed, M., Abdullah, T., Kousar, N., Shumaila, M. N., & Awais, M. (2018). Wireless body area network security and privacy issue in E-healthcare. International Journal of Advanced Computer Science and Applications, 9(4), 209–215.CrossRef
69.
70.
Kang, B., Wang, J., & Shao, D. (2017). Certificateless public auditing with privacy preserving for cloud-assisted wireless body area networks. Mobile Information Systems.
71.
Quwaider, M., & Jararweh, Y. (2017). Cloud-assisted data management in wireless body area networks. IJCSE, 14(1), 16–26.CrossRef
72.
Priya, N. S., et al. (2018). Security aware trusted cluster based routing protocol for wireless body sensor networks. Wireless Personal Communications, 102(4), 3393–3411.CrossRef
73.
Masdari, M., Ahmadzadeh, S., & Bidaki, M. (2017). Key management in wireless body area network: Challenges and issues. Journal of Network and Computer Applications, 91, 36–51.CrossRef
74.
Almuhaideb, A. M. (2021). Re-AuTh: Lightweight re-authentication with practical key management for wireless body area networks. Arabian Journal for Science and Engineering, 46(9), 8189–8202.CrossRef
75.
Tan, H., & Chung, I. (2018). A secure and efficient group key management protocol with cooperative sensor association in WBANs. Sensors (Basel, Switzerland), 18(11), 3930.CrossRef
76.
Dhanvijay, M. M., & Patil, S. C. (2022). Energy aware MAC protocol with mobility management in wireless body area network. Peer-to-Peer Networking and Applications, 15(1), 426–443.CrossRef
77.
Singla, R., Kaur, N., Koundal, D., Lashari, S. A., Bhatia, S., & Rahmani, M. K. I. (2021). Optimized energy efficient secure routing protocol for wireless body area network. IEEE Access: Practical Innovations, Open Solutions, 9, 116745–116759.CrossRef
78.
Joshi, A., & Mohapatra, A. K. (2019). Authentication protocols for wireless body area network with key management approach. Journal of Discrete Mathematical Sciences and Cryptography, 22(2), 219–240.CrossRef
79.
Manogaran, G., et al. (2018). A new architecture of internet of things and big data ecosystem for secured smart healthcare monitoring and alerting system. Future Generation Computer Systems, 82, 375–387.CrossRef
80.
Liu, X., Zhu, Y., Ge, Y., Wu, D., & Zou, B. (2016). A secure medical information management system for wireless body area networks. KSII Transactions on Internet & Information Systems, 10(1), 221–237.
81.
Alkhabet, M. M., & Ismail, M. (2021). Security algorithms for distributed storage system for E-health application over wireless body area network. Journal of Ambient Intelligence and Humanized Computing, 1–12.
82.
Wang, W., Shi, X., & Qin, T. (2019). Encryption-free authentication and integrity protection in body area networks through physical unclonable functions. Smart Health, 12, 66–81.CrossRef
83.
Ryu, H., & Kim, H. (2021, August). Privacy-preserving authentication protocol for wireless body area networks in healthcare applications. In Healthcare MDPI (Vol. 9, No. 9, p. 1114).
84.
Subramanian, A. K., Ghosh, U., Ramaswamy, S., Alnumay, W. S., & Sharma, P. K. (2021). PrEEMAC: Priority based energy efficient MAC protocol for wireless body sensor networks. Sustainable Computing: Informatics and Systems, 30, 100510.
85.
Jegadeesan, S., Azees, M., Babu, N. R., Subramaniam, U., & Almakhles, J. D. (2020). EPAW: Efficient privacy preserving anonymous mutual authentication scheme for wireless body area networks (WBANs). IEEE Access: Practical Innovations, Open Solutions, 8, 48576–48586.CrossRef
86.
Ahmed, S., Saqib, M., Adil, M., Ali, T., & Ishtiaq, A. (2017, November). Integration of cloud computing with internet of things and wireless body area network for effective healthcare. In 2017 International Symposium on Wireless Systems and Networks (ISWSN) IEEE (pp. 1–6).
87.
Sudarsono, A., Huda, S., Fahmi, N., Al-Rasyid, M. U. H., & Kristalina, P. (2016). Secure data exchange in environmental health monitoring system through wireless sensor network. International Journal of Engineering and Technology Innovation, 6(2), 103.
88.
Al Reshan, M., et al. (2019). MBPSKA: Multi-biometric and physiological signal-based key agreement for body area networks. IEEE Access: Practical Innovations, Open Solutions, 7, 78484–78502.CrossRef
89.
Shanmugavadivel, G., Gomathy, B., & Ramesh, S. M. (2021). An enhanced data security and task flow scheduling in cloud-enabled wireless body area network. Wireless Personal Communications, 120(1), 849–867.CrossRef
90.
Roy, S., & Biswas, S. (2019). A novel trust evaluation model based on data freshness in WBAN. In Proceedings of International ethical hacking conference (pp. 223–232).
91.
Mehmood, B., & Aadil, F. (2021). An efficient clustering technique for wireless body area networks based on dragonfly optimization. Internet of Things in Business Transformation: Developing an Engineering and Business Strategy for Industry, 5.0, 27–42.
92.
Hu, C., Li, H., Huo, Y., Xiang, T., & Liao, X. (2016). Secure and efficient data communication protocol for wireless body area networks. IEEE Transactions on Multi-Scale Computing Systems, 2(2), 94–107.CrossRef
93.
Ali, M., & Liu, X. (2022). Lightweight verifiable data management system for cloud-assisted wireless body area networks. Peer-to-Peer Networking and Applications, 15, 1–25.
94.
Ara, A., Al-Rodhaan, M., Tian, Y., & Al-Dhelaan, A. (2017). A secure privacy-preserving data aggregation scheme based on bilinear ElGamal cryptosystem for remote health monitoring systems. IEEE Access: Practical Innovations, Open Solutions, 5, 12601–12617.CrossRef
95.
Mohamed, M. B., Meddeb-Makhlouf, A., Fakhfakh, A., & Kanoun, O. (2021). Wireless body sensor networks with enhanced reliability by data aggregation based on machine learning algorithms. In O. Kanoun, N. Derbel (Eds.), Advanced Sensors for biomedical applications (pp. 67–81). Cham: Springer.
96.
Sharavanan, P. T., Sridharan, D., & Kumar, R. (2018). A privacy preservation secure cross layer protocol design for IoT based wireless body area networks using ECDSA framework. Journal of Medical Systems, 42(10), 196.CrossRef
97.
Liu, C. H., & Chung, Y. F. (2017). Secure user authentication scheme for wireless healthcare sensor networks. Computers & Electrical Engineering, 59, 250–261.CrossRef
Metadata
Title
A Review: Security and Privacy for Health Care Application in Wireless Body Area Networks
Authors
V. D. Gaikwad
S. Ananthakumaran
Publication date
21-03-2023
Publisher
Springer US
Published in
Wireless Personal Communications / Issue 1/2023
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI
https://doi.org/10.1007/s11277-023-10305-7

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