What is the environmental impact of a blood transfusion? A life cycle assessment of transfusion services across England

Author:

Hibbs Stephen P.1ORCID,Thomas Stephen2ORCID,Agarwal Nikhil3,Andrews Charlotte3,Eskander Sylvia3,Abdalla Aaliyah Sharif2,Staves Julie4,Eckelman Matthew J.3,Murphy Michael F.24ORCID

Affiliation:

1. Wolfson Institute of Population Health Queen Mary University of London London UK

2. NHS Blood and Transplant London UK

3. Department of Civil and Environmental Engineering Northeastern University Boston Massachusetts USA

4. Oxford University Hospitals NHS Foundation Trust Oxford UK

Abstract

AbstractBackgroundHealthcare activities significantly contribute to greenhouse gas (GHG) emissions. Blood transfusions require complex, interlinked processes to collect, manufacture, and supply. Their contribution to healthcare emissions and avenues for mitigation is unknown.Study Design and MethodsWe performed a life cycle assessment (LCA) for red blood cell (RBC) transfusions across England where 1.36 million units are transfused annually. We defined the process flow with seven categories: donation, transportation, manufacturing, testing, stockholding, hospital transfusion, and disposal. We used direct measurements, manufacturer data, bioengineering databases, and surveys to assess electrical power usage, embodied carbon in disposable materials and reagents, and direct emissions through transportation, refrigerant leakage, and disposal.ResultsThe central estimate of carbon footprint per unit of RBC transfused was 7.56 kg CO2 equivalent (CO2eq). The largest contribution was from transportation (2.8 kg CO2eq, 36% of total). The second largest was from hospital transfusion processes (1.9 kg CO2eq, 26%), driven mostly by refrigeration. The third largest was donation (1.3 kg CO2eq, 17%) due to the plastic blood packs. Total emissions from RBC transfusion are ~10.3 million kg CO2eq/year.DiscussionThis is the first study to estimate GHG emissions attributable to RBC transfusion, quantifying the contributions of each stage of the process. Primary areas for mitigation may include electric vehicles for the blood service fleet, improving the energy efficiency of refrigeration, using renewable sources of electricity, changing the plastic of blood packs, and using methods of disposal other than incineration.

Funder

Wellcome Trust

Publisher

Wiley

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