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Unveiling the Power of Blockchain in Pharmaceutical Supply Chains: Strengthening Security and Improving Drug Traceability

Year 2024, Volume: 11 Issue: 2, 142 - 151, 07.07.2024
https://doi.org/10.31202/ecjse.1338782

Abstract

Pharmaceutical supply chains involve multiple stakeholders at various stages, beginning with the API source, moving on to the medication manufacturer, packaging and distribution firms, administrative regulators, hospitals, pharmacies, and finally the patient. Because of the difficulty in tracking and ensuring authenticity, counterfeit drugs are more likely to penetrate the distribution system. Increasing counterfeit medicinal products in the markets are putting a potential threat to pharmaceutical supply chain and to life of innocent people. There is a need of technology that could provide privacy, trust, transparency, security, authorization, and authentication to the clients and show proof of origin of products. Due to significant qualities such as decentralisation, transparency, a trust-free environment, anonymity, and immutability, blockchain-based drug traceability provides a viable answer to this problem. Blockchain technology provides an efficient and cost-effective option for improving various drug traceability functions and procedures to assure appropriate identification. There are many other ways that blockchain is being used in the pharmaceutical industry, including the packaging and supply chain functions. This paper describes the challenges in pharmaceutical supply chain and how the blockchain combined with pharmaceutical supply chain can be a problem solver. We also provide a blockchain architectures for product traceability in the pharmaceutical supply chain system.

References

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  • [18] Guang Yang, Chunlei Li, and Kjell E Marstein. A blockchain-based architecture for securing electronic health record systems. Concurrency and Computation: Practice and Experience, 33(14):e5479, 2021.
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  • [20] Edvard Tijan, Saša Aksentijević, Katarina Ivanić, and Mladen Jardas. Blockchain technology implementation in logistics. Sustainability, 11(4):1185, 2019.
  • [21] Eman M Abou-Nassar, Abdullah M Iliyasu, Passent M El-Kafrawy, Oh-Young Song, Ali Kashif Bashir, and Ahmed A Abd El-Latif. Ditrust chain: towards blockchain-based trust models for sustainable healthcare iot systems. IEEE access, 8:111223–111238, 2020. [22] Rim Ben Fekih and Mariam Lahami. Application of blockchain technology in healthcare: a comprehensive study. In The Impact of Digital Technologies on Public Health in Developed and Developing Countries: 18th International Conference, ICOST 2020, Hammamet, Tunisia, June 24–26, 2020, Proceedings 18, pages 268–276. Springer, 2020.
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  • [24] Yanling Chang, Eleftherios Iakovou, and Weidong Shi. Blockchain in global supply chains and cross border trade: a critical synthesis of the state-of-the-art, challenges and opportunities. International Journal of Production Research, 58 (7):2082–2099, 2020.
  • [25] Bahar Houtan, Abdelhakim Senhaji Hafid, and Dimitrios Makrakis. A survey on blockchain-based self-sovereign patient identity in healthcare. IEEE Access, 8:90478–90494, 2020.
  • [26] Mohammed Alghazwi, Fatih Turkmen, Joeri Van Der Velde, and Dimka Karastoyanova. Blockchain for genomics: a systematic literature review. Distributed Ledger Technologies: Research and Practice, 1(2):1–28, 2022.
  • [27] Yonggang Xiao, Bin Xu, Wenhao Jiang, and Yunjun Wu. The healthchain blockchain for electronic health records: development study. Journal of medical Internet research, 23(1):e13556, 2021.
  • [28] Mikuláš Čern`y, Marián Gogola, Stanislav Kubal’ák, and Ján Ondruš. Blockchain technology as a new driver in supply chain. Transportation Research Procedia, 55:299–306, 2021.
  • [29] Funlade T Sunmola, Patrick Burgess, and Albert Tan. Building blocks for blockchain adoption in digital transformation of sustainable supply chains. Procedia Manufacturing, 55:513–520, 2021.
  • [30] Ahmad Musamih, Khaled Salah, Raja Jayaraman, Junaid Arshad, Mazin Debe, Yousof Al-Hammadi, and Samer Ellahham. A blockchain-based approach for drug traceability in healthcare supply chain. IEEE access, 9:9728–9743, 2021.
  • [31] Daniel Laverick and Zhang Haisheng. A blockchain-enabled solution to drive material traceability along the pharmaceutical supply chain in asia. pages 1–20. ., 2021.
  • [32] Manan Shukla, Jianjing Lin, and Oshani Seneviratne. Blockiot: blockchain-based health data integration using iot devices. In AMIA Annual Symposium Proceedings, volume 2021, page 1119. American Medical Informatics Association, 2021.
  • [33] H Schofield and L Thasarathakumar. Blockchain, covid-19 and the pharmaceutical supply chain. PharmExec, 2021.
Year 2024, Volume: 11 Issue: 2, 142 - 151, 07.07.2024
https://doi.org/10.31202/ecjse.1338782

Abstract

References

  • [1] David Chaum. Blind signatures for untraceable payments. In David Chaum, Ronald L. Rivest, and Alan T. Sherman, editors, Advances in Cryptology, pages 199–203, Boston, MA, 1983. Springer US. ISBN 978-1-4757-0602-4.
  • [2] David Chaum and Sandra Roijakkers. Unconditionally-secure digital signatures. In Advances in Cryptology-CRYPTO’90: Proceedings 10, pages 206–214. Springer, 1991.
  • [3] Adam Back et al. Hashcash-a denial of service counter-measure. Available at : http://www.hashcash.org/papers/hashcash.pdf, 2002.
  • [4] Nick Szabo. Bit gold: towards trust-independent digital money. Recuperado de:https://web.archive.org/web/20140406003811/http://szabo.best.vwh.net/bitgold.html, 1998.
  • [5] Wei Dai. B-money-an anonymous, distributed electronic cash system, 1998.
  • [6] Satoshi Nakamoto. Bitcoin: A peer-to-peer electronic cash system. Available at https://bitcoin.org/bitcoin.pdf, 2008.
  • [7] Mueen Uddin, Khaled Salah, Raja Jayaraman, Sasa Pesic, and Samer Ellahham. Blockchain for drug traceability: Architectures and open challenges. Health informatics journal, 27(2):14604582211011228, 2021.
  • [8] Sanjeev Kumar Dwivedi, Ruhul Amin, and Satyanarayana Vollala. Blockchain based secured information sharing protocol in supply chain management system with key distribution mechanism. Journal of Information Security and Applications, 54:102554, 2020.
  • [9] Seyednima Khezr, Md Moniruzzaman, Abdulsalam Yassine, and Rachid Benlamri. Blockchain technology in healthcare: A comprehensive review and directions for future research. Applied sciences, 9(9):1736, 2019.
  • [10] Haoyan Wu, Zhijie Li, Brian King, Zina Ben Miled, John Wassick, and Jeffrey Tazelaar. A distributed ledger for supply chain physical distribution visibility. Information, 8(4):137, 2017.
  • [11] Magnus Lyster Jochumsen and Atanu Chaudhuri. Blockchain’s impact on supply chain of a pharmaceutical company. In EUROMA Conference, volume 6, 2018.
  • [12] Kevin A Clauson, Elizabeth A Breeden, Cameron Davidson, and Timothy K Mackey. Leveraging blockchain technology to enhance supply chain management in healthcare:: An exploration of challenges and opportunities in the health supply chain. Blockchain in healthcare today, 2018.
  • [13] Jen-Hung Tseng, Yen-Chih Liao, Bin Chong, and Shih-wei Liao. Governance on the drug supply chain via gcoin blockchain. International journal of environmental research and public health, 15(6):1055, 2018.
  • [14] Koosha Mohammad Hossein, Mohammad Esmaeil Esmaeili, Tooska Dargahi, et al. Blockchain-based privacy-preserving healthcare architecture. In 2019 IEEE Canadian conference of electrical and computer engineering (CCECE), pages 1–4. IEEE, 2019.
  • [15] SR Bryatov and AA Borodinov. Blockchain technology in the pharmaceutical supply chain: Researching a business model based on hyperledger fabric. In Proceedings of the International Conference on Information Technology and Nanotechnology (ITNT), Samara, Russia, volume 10, pages 1613–0073, 2019.
  • [16] Faisal Jamil, Lei Hang, KyuHyung Kim, and DoHyeun Kim. A novel medical blockchain model for drug supply chain integrity management in a smart hospital. Electronics, 8(5):505, 2019.
  • [17] George Drosatos and Eleni Kaldoudi. Blockchain applications in the biomedical domain: a scoping review. Computational and structural biotechnology journal, 17:229–240, 2019.
  • [18] Guang Yang, Chunlei Li, and Kjell E Marstein. A blockchain-based architecture for securing electronic health record systems. Concurrency and Computation: Practice and Experience, 33(14):e5479, 2021.
  • [19] Raja Jayaraman, Khaled Salah, and Nelson King. Improving opportunities in healthcare supply chain processes via the internet of things and blockchain technology. International Journal of Healthcare Information Systems and Informatics (IJHISI), 14(2):49–65, 2019.
  • [20] Edvard Tijan, Saša Aksentijević, Katarina Ivanić, and Mladen Jardas. Blockchain technology implementation in logistics. Sustainability, 11(4):1185, 2019.
  • [21] Eman M Abou-Nassar, Abdullah M Iliyasu, Passent M El-Kafrawy, Oh-Young Song, Ali Kashif Bashir, and Ahmed A Abd El-Latif. Ditrust chain: towards blockchain-based trust models for sustainable healthcare iot systems. IEEE access, 8:111223–111238, 2020. [22] Rim Ben Fekih and Mariam Lahami. Application of blockchain technology in healthcare: a comprehensive study. In The Impact of Digital Technologies on Public Health in Developed and Developing Countries: 18th International Conference, ICOST 2020, Hammamet, Tunisia, June 24–26, 2020, Proceedings 18, pages 268–276. Springer, 2020.
  • [23] Moulouki Reda, Dominique Bernard Kanga, Taif Fatima, and Mohamed Azouazi. Blockchain in health supply chain management: State of art challenges and opportunities. Procedia Computer Science, 175:706–709, 2020.
  • [24] Yanling Chang, Eleftherios Iakovou, and Weidong Shi. Blockchain in global supply chains and cross border trade: a critical synthesis of the state-of-the-art, challenges and opportunities. International Journal of Production Research, 58 (7):2082–2099, 2020.
  • [25] Bahar Houtan, Abdelhakim Senhaji Hafid, and Dimitrios Makrakis. A survey on blockchain-based self-sovereign patient identity in healthcare. IEEE Access, 8:90478–90494, 2020.
  • [26] Mohammed Alghazwi, Fatih Turkmen, Joeri Van Der Velde, and Dimka Karastoyanova. Blockchain for genomics: a systematic literature review. Distributed Ledger Technologies: Research and Practice, 1(2):1–28, 2022.
  • [27] Yonggang Xiao, Bin Xu, Wenhao Jiang, and Yunjun Wu. The healthchain blockchain for electronic health records: development study. Journal of medical Internet research, 23(1):e13556, 2021.
  • [28] Mikuláš Čern`y, Marián Gogola, Stanislav Kubal’ák, and Ján Ondruš. Blockchain technology as a new driver in supply chain. Transportation Research Procedia, 55:299–306, 2021.
  • [29] Funlade T Sunmola, Patrick Burgess, and Albert Tan. Building blocks for blockchain adoption in digital transformation of sustainable supply chains. Procedia Manufacturing, 55:513–520, 2021.
  • [30] Ahmad Musamih, Khaled Salah, Raja Jayaraman, Junaid Arshad, Mazin Debe, Yousof Al-Hammadi, and Samer Ellahham. A blockchain-based approach for drug traceability in healthcare supply chain. IEEE access, 9:9728–9743, 2021.
  • [31] Daniel Laverick and Zhang Haisheng. A blockchain-enabled solution to drive material traceability along the pharmaceutical supply chain in asia. pages 1–20. ., 2021.
  • [32] Manan Shukla, Jianjing Lin, and Oshani Seneviratne. Blockiot: blockchain-based health data integration using iot devices. In AMIA Annual Symposium Proceedings, volume 2021, page 1119. American Medical Informatics Association, 2021.
  • [33] H Schofield and L Thasarathakumar. Blockchain, covid-19 and the pharmaceutical supply chain. PharmExec, 2021.
There are 32 citations in total.

Details

Primary Language English
Subjects Engineering Design
Journal Section Research Articles
Authors

Vandani Verma 0000-0003-4175-9227

Publication Date July 7, 2024
Submission Date August 7, 2023
Acceptance Date May 13, 2024
Published in Issue Year 2024 Volume: 11 Issue: 2

Cite

IEEE V. Verma, “Unveiling the Power of Blockchain in Pharmaceutical Supply Chains: Strengthening Security and Improving Drug Traceability”, El-Cezeri Journal of Science and Engineering, vol. 11, no. 2, pp. 142–151, 2024, doi: 10.31202/ecjse.1338782.
Creative Commons License El-Cezeri is licensed to the public under a Creative Commons Attribution 4.0 license.
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