A New Intuitionistic Fuzzy Multi-Criteria Decision-making Method for Designing Organ Transplantation Supply Chain Network Problem:  Golden Eagle Metaheuristic Algorithm

Salimian, Sina; Mousavi, Seyed Meysam

doi:10.22084/ier.2021.25077.2051

Obtaining permission to launch 5 new publications from the Ministry of Science, Research and Technology.

Number of Journals	22
Number of Issues	501
Number of Articles	5,252
Article View	9,906,545
PDF Download	6,602,421

	A New Intuitionistic Fuzzy Multi-Criteria Decision-making Method for Designing Organ Transplantation Supply Chain Network Problem: Golden Eagle Metaheuristic Algorithm
نشریه پژوهش های مهندسی صنایع در سیستم های تولید
Article 11, Volume 9, Issue 18, September 2021, Pages 179-195 PDF (722.81 K)
Document Type: Research Paper
DOI: 10.22084/ier.2021.25077.2051
Authors
Sina Salimian¹; Seyed Meysam Mousavi^* ²
¹Ph.D. Candidate, Department of Industrial Engineering, Faculty of Engineering, Shahed University, Tehran, Iran
²Associate Professor, Department of Industrial Engineering, Faculty of Engineering, Shahed University, Tehran, Iran
Abstract
In today's world, organ donation has been identified as a life-giving process worldwide and has been welcomed by many people in different societies. This process can increase the people's quality of life in various countries and also increase the level of social security. In this study, to investigate the issue of organ donation, a supply chain network is presented that includes three sections: donation hospitals, transplant centers, and recipient zones. Besides, to make the appropriate decision to select the best receiver, a new multi-criteria decision-making (MCDM) method is used under intuitionistic fuzzy conditions. Then the proposed mathematical model is presented. In this model, the requirements of climate change and its effects on the transportation system, the quality of organs affected by cold ischemic time, and queuing in transplant centers are examined. A new decision-making method to select the best type of organ recipient and benefit from mathematical modeling provides to apply the issues of organ quality, climate change risk, and the concept of queuing that are the strengths points and innovations of this paper. Then, after presenting the model, using a compromise solution approach, the proposed multi-objective model with the objectives of cost, time, and quality of the organs becomes an equivalent one-objective model. Then, a golden eagle meta-heuristic algorithm is used to solve the problem. Finally, a practical example validates the decision-making method and the proposed mathematical model.
Keywords
Multi-criteria decision-making; Intuitionistic fuzzy; Transplant network design; Compromise solution; Golden eagle algorithm

References
Vong, G. (2017). The ethical asymmetry between a head. body transplant and multiple organ transplants: overall health, justice, and risk. AJOB Neuroscience, 8(4), 217-219. Zahiri, B., Tavakkoli-Moghaddam, R., & Pishvaee, M. S. (2014). A robust possibilistic programming approach to multi-period location–allocation of organ transplant centers under uncertainty. Computers & Industrial Engineering, 74, 139-148. Neumann, U. P., Langrehr, J. M., Kaisers, U., Lang, M., Schmitz, V., & Neuhaus, P. (2002). Simultaneous splenectomy increases risk for opportunistic pneumonia in patients after live transplantation. Transplant international, 15(5), 226-232. Lindemann, J., Dageforde, L. A., Brockmeier, D., Vachharajani, N., Scherer, M., Chapman, W., & Doyle, M. B. M. (2019). Organ procurement center allows for daytime liver transplantation with less resource utilization: may address burnout, pipeline, and safety for field of transplantation. American Journal of Transplantation, 19(5), 1296-1304. Çay, P. (2012). Organ transplantation logistics: case for Turkey(Doctoral dissertation, Bilkent University). Thompson, D., Waisanen, L., Wolfe, R., Merion, R. M., McCullough, K., & Rodgers, A. (2004). Simulating the allocation of organs for transplantation. Health care management science, 7(4), 331-338. Kazemeyni, S. M., Bagheri, C. A., & Heidary, A. R. (2004). Worldwide cadaveric organ donation systems (transplant organ procurement). Zahiri, B., Tavakkoli-Moghaddam, R., Mohammadi, M., & Jula, P. (2014). Multi-objective design of an organ transplant network under uncertainty. Transportation Research Part E: Logistics and Transportation Review, 72, 101-124. Ponticelli, C. E. (2015). The impact of cold ischemia time on renal transplant outcome. Kidney international, 87(2), 272-275. Sturmberg, J. P., Churilov, L., & McDonnell, G. (2013). Modelling. In Handbook of systems and complexity in health(pp. 81-111). Springer, New York, NY. Valls, A., Moreno, A., & Sánchez, D. (2002). A Multi-Criteria Decision Aid Agent Applied to the Selection of the Best Receiver in a Transplant. In ICEIS(pp. 431-438). La Scalia, G., Aiello, G., Rastellini, C., Micale, R., & Cicalese, L. (2011). Multi-criteria decision-making support system for pancreatic islet transplantation. Expert Systems with Applications, 38(4), 3091-3097. گلزار راغب، سعید، موسوی، سید میثم، گیتی نورد، حسین، وحدانی، بهنام. (2016). مدل تصمیم گیری گروهی سازشی فازی تردیدی با درنظر گرفتن وزن تصمیم گیران به‌منظور ارزیابی ریسک های ایمنی در پروژه های تولیدی (صنعت کشتی سازی).نشریه پژوهش های مهندسی صنایع در سیستم های تولید،4(7)، 93-103.‎ Zhang, H. C., & Huang, S. H. (1994). A fuzzy approach to process plan selection. The international journal of production research, 32(6), 1265-1279. Gao, J., Guo, F., Ma, Z., & Huang, X. (2021). Multi-criteria decision-making framework for large-scale rooftop photovoltaic project site selection based on intuitionistic fuzzy sets. Applied Soft Computing, 102, 107098. Torabi, S. A., & Hassini, E. (2008). An interactive possibilistic programming approach for multiple objective supply chain master planning. Fuzzy sets and systems, 159(2), 193-214. Beliën, J., De Boeck, L., Colpaert, J., Devesse, S., & Van den Bossche, F. (2013). Optimizing the facility location design of organ transplant centers. Decision Support Systems, 54(4), 1568-1579. Caruso, V., & Daniele, P. (2018). A network model for minimizing the total organ transplant costs. European Journal of Operational Research, 266(2), 652-662. Aghazadeh, S. M., Mohammadi, M., & Naderi, B. (2018). Robust bi-objective cost-effective, multi-period, location-allocation organ transplant supply chain. International Journal of Logistics Systems and Management, 29(1), 17-36. Savaşer, S., Kınay, Ö. B., Kara, B. Y., & Cay, P. (2019). Organ transplantation logistics: a case for Turkey. OR Spectrum, 41(2), 327-356. Kargar, B., Pishvaee, M. S., Jahani, H., & Sheu, J. B. (2020). Organ transportation and allocation problem under medical uncertainty: A real case study of liver transplantation. Transportation Research Part E: Logistics and Transportation Review, 134, 101841. Rouhani, S., Pishvaee, M., & Zarrinpoor, N. (2021). A fuzzy optimization approach to strategic organ transplantation network design problem: A real case study. Decision Science Letters, 10(3), 195-216. Anukokila, P., Anju, A., & Radhakrishnan, B. (2019). Optimality of intuitionistic fuzzy fractional transportation problem of type-2. Arab Journal of Basic and Applied Sciences, 26(1), 519-530. Ejegwa, P. A., Akubo, A. J., & Joshua, O. M. (2014). Intuitionistic fuzzy set and its application in career determination via normalized Euclidean distance method. European scientific journal, 10(15). Khatibi, V., & Montazer, G. A. (2009). Intuitionistic fuzzy set vs. fuzzy set application in medical pattern recognition. Artificial Intelligence in Medicine, 47(1), 43-52. Atanassov, K., & Gargov, G. (1989). Interval-valued intuitionistic fuzzy sets. Fuzzy Sets and Systems, 31(3), 343–349. Atanassov, K. T. (1994). New operations defined over the intuitionistic fuzzy sets. Fuzzy sets and Systems, 61(2), 137-142. Xu, Z., & Yager, R. R. (2006). Some geometric aggregation operators based on intuitionistic fuzzy sets. International journal of general systems, 35(4), 417-433. Yue, Z. (2014). Aggregating crisp values into intuitionistic fuzzy number for group decision making. Applied Mathematical Modelling, 38(11-12), 2969-2982. Liu, N., & Xu, Z. (2021). An overview of ARAS method: Theory development, application extension, and future challenge. International Journal of Intelligent Systems, 36(7), 3524-3565. Mehlawat, M. K., & Gupta, P. (2016). A new fuzzy group multi-criteria decision making method with an application to the critical path selection. The International Journal of Advanced Manufacturing Technology, 83(5-8), 1281-1296. Heidary Dahooie, J., Beheshti Jazan Abadi, E., Vanaki, A. S., & Firoozfar, H. R. (2018). Competency‐based IT personnel selection using a hybrid SWARA and ARAS‐G methodology. Human Factors and Ergonomics in Manufacturing & Service Industries, 28(1), 5-16. Büyüközkan, G., & Güler, M. (2020). Smart watch evaluation with integrated hesitant fuzzy linguistic SAW-ARAS technique. Measurement, 153, 107353. Dorfeshan, Y., Mousavi, S. M., Zavadskas, E. K., & Antucheviciene, J. (2021). A New Enhanced ARAS Method for Critical Path Selection of Engineering Projects with Interval Type-2 Fuzzy Sets. International Journal of Information Technology & Decision Making, 20(1), 37-65. Ghenai C, Albawab M, Bettayeb M (2019) Sustainability indicators for renewable energy systems using multi-criteria decision-making model and extended SWARA/ARAS hybrid method. Renew Energy 146:580–597 Matzarakis, A., Blazejczyk, K., & Amelung, B. (2007). Climate change and tourism assessment and coping strategies. Freiburg: Maastricht-Warsaw. Ha, J. W., & Kim, S. J. (1997). Solid Organ Transplantation in Korea: 1996. The Journal of the Korean Society for Transplantation, 11(2), 183-130. Valls, A., & Moreno, A. (2003). Assisting the Spanish Organ Transplant Coordination Process with Multi-Agent Systems. In Applications of Software Agent Technology in the Health Care Domain(pp. 181-197). Birkhäuser, Basel. Mosallaeipour, S., Mahmoodirad, A., Niroomand, S., & Vizvari, B. (2018). Simultaneous selection of material and supplier under uncertainty in carton box industries: a fuzzy possibilistic multi-criteria approach. Soft computing, 22(9), 2891-2905. حاجی سلطانی، مهدی، سیف برقی. (2020). ارائه مدلی چندهدفه برای مکان‌یابی-تخصیص سیستم‌های مراقبت سلامت پیشگیرانه با تقاضای احتمالی.نشریه پژوهش های مهندسی صنایع در سیستم های تولید،8(16)، 15-37.‎ Golabi, M., Izbirak, G., & Arkat, J. (2018). Multiple-server facility location problem with stochastic demands along the network edges. Journal of Engineering Research, 6(4). Karimi-Mamaghan, M., Mohammadi, M., Pirayesh, A., Karimi-Mamaghan, A. M., & Irani, H. (2020). Hub-and-spoke network design under congestion: A learning based metaheuristic. Transportation Research Part E: Logistics and Transportation Review, 142, 102069. Shakil, M., Fuad Yousif Mohammed, A., Arul, R., Bashir, A. K., & Choi, J. K. (2019). A novel dynamic framework to detect DDoS in SDN using metaheuristic clustering. Transactions on Emerging Telecommunications Technologies, e3622. Mohammadi-Balani, A., Nayeri, M. D., Azar, A., & Taghizadeh-Yazdi, M. (2021). Golden eagle optimizer: A nature-inspired metaheuristic algorithm. Computers & Industrial Engineering, 152, 107050. Rouyendegh, B. D., Yildizbasi, A., & Üstünyer, P. (2020). Intuitionistic fuzzy TOPSIS method for green supplier selection problem. Soft Computing, 24(3), 2215-2228. Nemes, B., Gámán, G., Polak, W. G., Gelley, F., Hara, T., Ono, S., & Eguchi, S. (2016). Extended-criteria donors in liver transplantation Part II: reviewing the impact of extended-criteria donors on the complications and outcomes of liver transplantation. Expert review of gastroenterology & hepatology, 10(7), 841-859
Statistics Article View: 560 PDF Download: 426

Journal management system. designed by sinaweb

Related Links

News

Statistics

A New Intuitionistic Fuzzy Multi-Criteria Decision-making Method for Designing Organ Transplantation Supply Chain Network Problem: Golden Eagle Metaheuristic Algorithm