Scalable and Secure Sharing of Personal Health Records in Cloud Computing using Attribute-based Encryption

TitleScalable and Secure Sharing of Personal Health Records in Cloud Computing using Attribute-based Encryption
Publication TypeJournal Article
Year of Publication2013
AuthorsLi, M., S. Yu, K. R. Yao Zheng, and W. Lou
Refereed DesignationRefereed
JournalIEEE Transactions on Parallel and Distributed Systems
Volume24
Start Page131
Issue1
Pagination131-143
Date Published01/2013
Abstract

Personal health record (PHR) is an emerging patient-centric model of health information exchange, which is often outsourced to be stored at a third party, such as cloud providers. However, there have been wide privacy concerns as personal health information could be exposed to those third party servers and to unauthorized parties. To assure the patients' control over access to their own PHRs, it is a promising method to encrypt the PHRs before outsourcing. Yet, issues such as risks of privacy exposure, scalability in key management, flexible access, and efficient user revocation, have remained the most important challenges toward achieving fine-grained, cryptographically enforced data access control. In this paper, we propose a novel patient-centric framework and a suite of mechanisms for data access control to PHRs stored in semitrusted servers. To achieve fine-grained and scalable data access control for PHRs, we leverage attribute-based encryption (ABE) techniques to encrypt each patient's PHR file. Different from previous works in secure data outsourcing, we focus on the multiple data owner scenario, and divide the users in the PHR system into multiple security domains that greatly reduces the key management complexity for owners and users. A high degree of patient privacy is guaranteed simultaneously by exploiting multiauthority ABE. Our scheme also enables dynamic modification of access policies or file attributes, supports efficient on-demand user/attribute revocation and break-glass access under emergency scenarios. Extensive analytical and experimental results are presented which show the security, scalability, and efficiency of our proposed scheme.

DOI10.1109/TPDS.2012.97