Collaborative Reverse Logistics Network for Infectious Medical Waste Management during the COVID-19 Outbreak

Liu, Xuan; Liao, Wenzhu

doi:10.3390/ijerph19159735

Cited by 13 publications

(6 citation statements)

References 56 publications

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“…The developed MILP concentrated on vaccination waste management more than other medical wastes. Luo and Liao (2022) conceptualized RSC for the COVID-19 outbreak by designing a multi-component routing-location optimization model. Also, they firstly armed the distribution processes by mobile processing centers to improve the network’s agility.…”

Section: Literature Reviewmentioning

confidence: 99%

The IoT-enabled sustainable reverse supply chain for COVID-19 Pandemic Wastes (CPW)

Mosallanezhad

Gholian-Jouybari

Cárdenas–Barrón

et al. 2023

Engineering Applications of Artificial Intelligence

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Section: Literature Reviewmentioning

confidence: 99%

The IoT-enabled sustainable reverse supply chain for COVID-19 Pandemic Wastes (CPW)

Mosallanezhad

Gholian-Jouybari

Cárdenas–Barrón

et al. 2023

Engineering Applications of Artificial Intelligence

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“…Many experts study the integrated location-routing problem in medical waste logistics from various perspectives such as economic, environmental, and multiple time periods. These include location-routing models for medical waste [6], dual-level equilibrium location-allocation optimization models [4], and multi-objective programming models [7] to comprehensively address decisions related to the location selection and transportation of medical waste disposal facilities. However, since medical waste contains tissues containing pathogenic microorganisms such as a patient's vomit and body fluids, as well as disposable instruments, needles, syringes, surgical blades, syringes, and other wastes used in operating theatres, emergency rooms, and injection rooms, etc., which have a certain degree of viral transmissibility, and these wastes are prone to cause environmental contamination and the spread of pathogens in the reverse logistic activities, the traditional optimization methods are only concerned with the minimization of the costs, which are not able to satisfy the current demand for the disposal of medical wastes.…”

Section: Introductionmentioning

confidence: 99%

Reverse Logistics Network Design for Medical Waste Disposal under the Scenario of Uncertain Proposal Demand

Zhu,

Ding,

Liu

2024

Sustainability

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With the development of the healthcare industry, the demand for medical services and protective equipment is boosted, causing the generation rate of infectious medical waste to increase rapidly. Therefore, it is of utmost importance for decision makers to effectively predict the potential risks and propose corresponding solutions. This paper investigates the reverse logistics network optimization for medical waste under the conditions of an uncertain proposal demand. Firstly, a prediction model of medical waste based on the SEIR epidemiological dynamics is constructed, in which both routine and public health emergency scenarios are simultaneously considered. Secondly, a bi-objective location-routing optimization model for a medical waste reverse logistics network is proposed, by simultaneously optimizing the total economic cost and potential risk throughout the entire logistics process. Subsequently, an NSGA-II algorithm is designed for a model solution in response to the model’s characteristics. The epidemiological dynamics-based prediction model is validated by the real case to be scientifically effective in predicting the amount of generated medical waste with a mean absolute percentage error (MAPE) of 18.08%. The constructed reverse logistics network model and the NSGA II algorithm provide a medical waste process center location, transportation routing, and vehicle selection solutions for both routine and emergency public health cases of Xi’an city with large, medium, and small scales. The above results indicate that the research scheme proposed in this paper could significantly reduce the medical waste logistics-related risks and costs and provide decision makers with more safe and reliable logistical solutions.

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“…Farrokhi-Asl et al [15] quantified health and environmental impacts as the number of people who might be impacted by the hazardous waste, and the total emission incurred from the distance travelled and technology deployed. Luo and Liao [23] optimized locations and routing of mobile medical waste collection units by considering both economic and environmental impacts. Entezaminia et al [13] assessed several environmental criteria using scores for those which they wanted to minimize.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, the problem has been extended to consider several locations of the needed facilities at the same time. This multi-facility location problem has been modelled in many applications, such as in determining collection and recycling centers in green supply chain by Entezaminia et al [13], deciding the locations of explosive waste recycling depots by Zhao and Zhu [22], and locating proper sites for mobile infectious waste processing centers by Luo and Liao [23]. Each of these studies also considers two competing objectives simultaneously in optimizing their problems.…”

Section: Introductionmentioning

confidence: 99%

A Multi-Objective Optimization Model for Multi-Facility Decisions of Infectious Waste Transshipment and Disposal

Kailomsom

Khompatraporn

2023

Sustainability

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Infectious waste disposal is a crucial concern in many areas. Not only is the waste obnoxious, but it can also pose a vital risk to human health. Disposal of infectious waste incurs higher costs than general waste disposal and must abide by stricter regulations. In this paper, the infectious waste disposal is formulated as a multi-objective optimization model. The objectives encompass economic, social, and environmental concerns. To save cost, waste transshipment facilities to function as consolidation points are proposed and integrated in the model. The economic objective includes construction and operational costs of the transshipment and disposal facilities. The social objective considers the communities surrounding the disposal facilities, while carbon dioxide emission is used as the measure in the environmental objective. The model is reformulated based on the lexicographic weighted Tchebycheff method to ensure that the Pareto frontier of the solutions is obtained. Then the model is applied to a health region in Thailand. Daily and every-other-day waste collection intervals are compared to examine additional benefits. Certain sensitivity of the solutions is also analyzed. After comparing several solutions, a compromise among all three objectives is suggested. It is composed of three transshipment and two disposal facilities, each with 1000 kg capacity. Moreover, if the solution is executed with the every-other-day waste collection interval, the overall costs can be saved. A sensitivity analysis of the solution on fuel price found that the solution was not very sensitive against an increase in the fuel price, in that when the fuel price increased by 20% the overall costs only increased by 7%. Lastly, when the daily infectious wastes are doubled, all the objective function values rise, ranging from 56% to 163%. The new solution suggests an increase in the number of the disposal facilities to four, but a decrease of the transshipment ones to only two.

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Collaborative Reverse Logistics Network for Infectious Medical Waste Management during the COVID-19 Outbreak

Cited by 13 publications

References 56 publications

The IoT-enabled sustainable reverse supply chain for COVID-19 Pandemic Wastes (CPW)

The IoT-enabled sustainable reverse supply chain for COVID-19 Pandemic Wastes (CPW)

Reverse Logistics Network Design for Medical Waste Disposal under the Scenario of Uncertain Proposal Demand

A Multi-Objective Optimization Model for Multi-Facility Decisions of Infectious Waste Transshipment and Disposal

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