Heterogeneity of Blood Processing and Storage Additives in Different Centers Impacts Stored Red Blood Cell Metabolism As Much As Storage Time: Lessons from REDS-III-Omics

Overview

Journal Transfusion

Specialty Hematology

Date 2018 Oct 25

PMID 30353560

Citations 55

Authors

Angelo DAlessandro

Rachel Culp-Hill

Julie A Reisz

Mikayla Anderson

Xiaoyun Fu

Travis Nemkov

Sarah Gehrke

Connie Zheng

Tamir Kanias

Yuelong Guo

Grier Page

Mark T Gladwin

Steve Kleinman

Marion Lanteri

Mars Stone

Michael Busch

James C Zimring

Affiliations

Soon will be listed here.

Abstract

Background: Biological and technical variability has been increasingly appreciated as a key factor impacting red blood cell (RBC) storability and, potentially, transfusion outcomes. Here, we performed metabolomics analyses to investigate the impact of factors other than storage duration on the metabolic phenotypes of stored RBC in a multicenter study.

Study Design And Methods: Within the framework of the REDS-III (Recipient Epidemiology and Donor Evaluation Study-III) RBC-Omics study, 13,403 donors were enrolled from four blood centers across the United States and tested for the propensity of their RBCs to hemolyze after 42 days of storage. Extreme hemolyzers were recalled and donated a second unit of blood. Units were stored for 10, 23, and 42 days prior to sample acquisition for metabolomics analyses.

Results: Unsupervised analyses of metabolomics data from 599 selected samples revealed a strong impact (14.2% of variance) of storage duration on metabolic phenotypes of RBCs. The blood center collecting and processing the units explained an additional 12.2% of the total variance, a difference primarily attributable to the storage additive (additive solution 1 vs. additive solution 3) used in the different hubs. Samples stored in mannitol-free/citrate-loaded AS-3 were characterized by elevated levels of high-energy compounds, improved glycolysis, and glutathione homeostasis. Increased methionine metabolism and activation of the transsulfuration pathway was noted in samples processed in the center using additive solution 1.

Conclusion: Blood processing impacts the metabolic heterogeneity of stored RBCs from the largest multicenter metabolomics study in transfusion medicine to date. Studies are needed to understand if these metabolic differences influenced by processing/storage strategies impact the effectiveness of transfusions clinically.

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