Optimizing the COVID-19 cold chain vaccine distribution network with medical waste management: A robust optimization approach

This paper investigates the distribution problem of the COVID-19 vaccine at the provincial level in Turkey and the management of medical waste, considering the cold chain requirements and the perishable nature of vac-cines. In this context, a novel multi-period multi-objective mixed-integer linear programming model is initially presented over a 12-month planning horizon for solving the deterministic distribution problem. The model in-cludes newly structured constraints due to the feature of COVID-19 vaccines, which must be administered in two doses at specified intervals. Then, the presented model is tested for the province of Izmir with deterministic data, and the results show that the demand can be satisfied and community immunity can be achieved in the specified planning horizon. Moreover, for the first time, a robust model is created using polyhedral uncertainty sets to manage uncertainties related to supply and demand quantities, storage capacity, and deterioration rate, and it has been analyzed under different uncertainty levels. Accordingly, as the level of uncertainty increases, the percentage of meeting the demand gradually decreases. It is observed that the biggest effect here is the uncer-tainty in supply, and in the worst case, approximately 30% of the demand cannot be met.

Automated summary

This paper investigates the distribution problem of the COVID-19 vaccine in Turkey at the provincial level, taking into account the cold chain requirements and perishable nature of the vaccines. A multi-period multi-objective mixed-integer linear programming model is presented to solve the deterministic distribution problem. The model includes newly structured constraints for COVID-19 vaccines administered in two doses at specified intervals. The results show that the demand can be satisfied in the specified planning horizon, and a robust model is created to manage uncertainties related to supply and demand quantities, storage capacity, and deterioration rate.