Big Data Analytics in Healthcare — A Systematic Literature Review and Roadmap for Practical Implementation

Sohail Imran; Tariq Mahmood; Ahsan Morshed; Timos Sellis

doi:10.1109/JAS.2020.1003384

Volume 8 Issue 1

Jan. 2021

IEEE/CAA Journal of Automatica Sinica

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Sohail Imran, Tariq Mahmood, Ahsan Morshed and Timos Sellis, "Big Data Analytics in Healthcare — A Systematic Literature Review and Roadmap for Practical Implementation," IEEE/CAA J. Autom. Sinica, vol. 8, no. 1, pp. 1-22, Jan. 2021. doi: 10.1109/JAS.2020.1003384

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Sohail Imran, Tariq Mahmood, Ahsan Morshed and Timos Sellis, "Big Data Analytics in Healthcare — A Systematic Literature Review and Roadmap for Practical Implementation," IEEE/CAA J. Autom. Sinica, vol. 8, no. 1, pp. 1-22, Jan. 2021. doi: 10.1109/JAS.2020.1003384

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Big Data Analytics in Healthcare — A Systematic Literature Review and Roadmap for Practical Implementation

doi: 10.1109/JAS.2020.1003384

Funds: This work was supported by two research grants provided by the Karachi Institute of Economics and Technology (KIET) and the Big Data Analytics Laboratory at the Insitute of Business Administration (IBA-Karachi)

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Author Bio:
Sohail Imran is an Assistant Professor and a doctoral candidate at the PAF-Karachi Institute of Economics and Technology, Pakistan. He has more than 15 years teaching experience in databases, data science, and big data analytics, and more than 10 years of training experience in databases (SQL and NoSQL), big data infrastructure, and data science for different institutes, universities, and the corporate sector. His research work is focused on mapping OLAP data warehousing schema into the distributed Hadoop environment. Specifically, he has developed a framework which creates dimension and fact tables over Hbase and Hive in a NoSQL schema-less manner and computes aggregates through SQL-overHadoop technologies (Presto, Drill, Spark SQL). This functionality is made scalable through containerization and more efficient through the use of Apache Spark

Tariq Mahmood is an Associate Professor at the Faculty of Computer Science, Institute of Business Administration (IBA), Pakistan. He received the Ph.D. degree in machine learning from University of Trento, Italy, and the M.S. degree in statistical machine learning from Universite Pierre et Marie Curie (Paris 6), France. He has published around 20 international journal and 35 conference publications with total 691 citations and h-index of 12 (Google Scholar). His research interests include BDA, deep learning and machine learning/data science. He heads the Big Data Analytics Laboratory at IBA, with the focus on imparting data science and big data certifications to students and industry professionals, implementing BDA-related industrial projects and researching in BDA technology stack, particularly to develop BDA architectures for different types of streaming and non-streaming data. He also consults in various local industries regarding business intelligence, data governance, BDA, and machine learning

Ahsan Morshed is a Lecturer in ICT at CQ University, Australia. Previously, he was a Research Fellow in Data Analytics at Swinburne University of Technology and a Senior Project Officer at RMIT University. He was also a Postdoctoral Fellow at CSIRO (Australia) on sensor data integration and machine learning, and an Information Management Specialist in the OEKC division at Food and Agriculture Organization (FAO) of UN in Rome, Italy. During his time in FAO, he acquired extensive skills in metadata standards, knowledge organization systems, ontologies, Linked Open Data management and information management tools. His research interests are the big data, data science, semantic web, linked open data and semantic machine learning. He holds the Ph.D. degree from the University of Trento, Italy. Dr. Morshed has 50 peer-reviewed publications (book, book chapter, journals, conference and workshop papers), with 229 citations and an h-index of 6 (Google Scholar)

Timos Sellis (F’09) is a Professor at Swinburne University of Technology, Australia. He holds the diploma from National Technical University of Athens (NTUA), Greece, the M.Sc. degree from Harvard University, USA, and the Ph.D. degree from the University of California at Berkeley, USA. Timos has a significant international research reputation in big data, data analytics, data integration and spatiotemporal database systems. He is a Fellow of the Association for Computing Machinery (ACM) for his contributions to database query optimisation, spatial data management and data warehousing and also an Institute of Electrical and Electronics Engineers (IEEE) Fellow for his contributions to database query optimisation and spatial data management. In 2018 he was awarded the IEEE TCDE Impact Award, in recognition of his impact in the field and for contributions to database systems research and broadening the reach of data engineering research. Before joining Swinburne, Timos was the Director of the Institute for Management of Information Systems and Professor at the National Technical University of Athens. He has also held the role of Director, Big Data Lab at RMIT University
Corresponding author: T. Mahmood is with the Faculty of Computer Science, Institute of Business Administration, Karachi 75270, Pakistan (e-mail: tmahmood@iba.edu.pk)
¹ https://neo4j.com
² http://www.hl7.org/implement/standards/fhir/)
³ A group of graduate students participated in this activity over a period of 3 months. For the sake of brevity, the details are outside the scope of this paper.
⁴ To the best of our knowledge, this list is complete as of June 2020.
⁵ A detailed discussion of the nine compared papers is outside the scope of this work; we invite the reader to go through these papers for more required information.
Received Date: 2020-06-29
Revised Date: 2020-07-21
Accepted Date: 2020-07-22

Abstract

Abstract

The advent of healthcare information management systems (HIMSs) continues to produce large volumes of healthcare data for patient care and compliance and regulatory requirements at a global scale. Analysis of this big data allows for boundless potential outcomes for discovering knowledge. Big data analytics (BDA) in healthcare can, for instance, help determine causes of diseases, generate effective diagnoses, enhance QoS guarantees by increasing efficiency of the healthcare delivery and effectiveness and viability of treatments, generate accurate predictions of readmissions, enhance clinical care, and pinpoint opportunities for cost savings. However, BDA implementations in any domain are generally complicated and resource-intensive with a high failure rate and no roadmap or success strategies to guide the practitioners. In this paper, we present a comprehensive roadmap to derive insights from BDA in the healthcare (patient care) domain, based on the results of a systematic literature review. We initially determine big data characteristics for healthcare and then review BDA applications to healthcare in academic research focusing particularly on NoSQL databases. We also identify the limitations and challenges of these applications and justify the potential of NoSQL databases to address these challenges and further enhance BDA healthcare research. We then propose and describe a state-of-the-art BDA architecture called Med-BDA for healthcare domain which solves all current BDA challenges and is based on the latest zeta big data paradigm. We also present success strategies to ensure the working of Med-BDA along with outlining the major benefits of BDA applications to healthcare. Finally, we compare our work with other related literature reviews across twelve hallmark features to justify the novelty and importance of our work. The aforementioned contributions of our work are collectively unique and clearly present a roadmap for clinical administrators, practitioners and professionals to successfully implement BDA initiatives in their organizations.
- Big data analytics (BDA),
- big data architecture,
- healthcare,
- NoSQL data stores,
- patient care,
- roadmap,
- systematic literature review

FullText(HTML)

¹ https://neo4j.com
² http://www.hl7.org/implement/standards/fhir/)
³ A group of graduate students participated in this activity over a period of 3 months. For the sake of brevity, the details are outside the scope of this paper.
⁴ To the best of our knowledge, this list is complete as of June 2020.
⁵ A detailed discussion of the nine compared papers is outside the scope of this work; we invite the reader to go through these papers for more required information.

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The most thorough systematic literature review on big data analytics applications to healthcare
Focus on healthcare applications for NoSQL databases and Apache Hadoop ecosystem
Proposes the first-ever Zeta architecture called Med-BDA for big healthcare data analytics
Med-BDA has the potential to solve ALL current limitations for big healthcare data analytics
We present business strategies to successfully implement Med-BDA in any clinical organization

Big Data Analytics in Healthcare — A Systematic Literature Review and Roadmap for Practical Implementation

doi: 10.1109/JAS.2020.1003384

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