Altered timing of riboflavin and ultraviolet light pathogen inactivation improves platelet in vitro quality.

BACKGROUND: The platelet (PLT) storage lesion is in part caused by the collection and/or production process. Pathogen inactivation (PI) further accelerates its development leading to a reduced in vitro PLT functionality and hence quality. Although the treatment of PLT concentrates (PCs) with riboflavin and ultraviolet light PI should occur within 22 hours of collection, in this study the impact of treatment timing on in vitro PLT quality was investigated. STUDY DESIGN AND METHODS: Apheresis PCs were PI treated on the day of production or on Days 1, 3, or 4 of storage or left untreated as control. A panel of in vitro variables was used to monitor quality throughout 7-day storage, including metabolism, PLT activation, and release of microparticles. Changes in phosphorylation profiles of proteins in the lysate and levels of PLT factor 4, thrombospondin, and epidermal growth factor (EGF) in the releasate were analyzed by immunoblots or enzyme-linked immunosorbent assay. RESULTS: By Day 7 of storage, units illuminated on Day 4 showed a smaller impact of the PI process than units treated on the day of production or one day after on PLT quality such as PLT activation; metabolic activity; microvesicle and EGF release; and phosphorylation of p38, ERK, and HSP27. PCs treated on Day 3 of storage displayed an intermediate effect. CONCLUSION: The timing of PI treatment of PCs influences in vitro PLT quality. Based on these results, timing recommendations should be reconsidered. If PI is applied, inventory management in blood banks might improve with a more flexible collection and treatment regime.

Whole blood treated with riboflavin and ultraviolet light: quality assessment of all blood components produced by the buffy coat method.

BACKGROUND: Pathogen inactivation (PI) technologies are currently licensed for use with platelet (PLT) and plasma components. Treatment of whole blood (WB) would be of benefit to the blood banking community by saving time and costs compared to individual component treatment. However, no paired, pool-and-split study directly assessing the impact of WB PI on the subsequently produced components has yet been reported. STUDY DESIGN AND METHODS: In a "pool-and-split" study, WB either was treated with riboflavin and ultraviolet (UV) light or was kept untreated as control. The buffy coat (BC) method produced plasma, PLT, and red blood cell (RBC) components. PLT units arising from the untreated WB study arm were treated with riboflavin and UV light on day of production and compared to PLT concentrates (PCs) produced from the treated WB units. A panel of common in vitro variables for the three types of components was used to monitor quality throughout their respective storage periods. RESULTS: PCs derived from the WB PI treatment were of significantly better quality than treated PLT components for most variables. RBCs produced from the WB treatment deteriorated earlier during storage than untreated units. Plasma components showed a 3% to 44% loss in activity for several clotting factors. CONCLUSION: Treatment of WB with riboflavin and UV before production of components by the BC method shows a negative impact on all three blood components. PLT units produced from PI-treated WB exhibited less damage compared to PLT component treatment.

Protein translation occurs in platelet concentrates despite riboflavin/UV light pathogen inactivation treatment.

PURPOSE: Pathogen inactivation technologies (PITs) were introduced into blood banking to further improve the safety of blood products. However, the UV light used in PITs to terminate pathogen growth might alter the functionality of the cells in the blood product as well as the protein profile of the blood components. This study employed proteomic approaches to assess changes in the platelet proteome and translatome. EXPERIMENTAL DESIGN: Apheresis-derived platelet concentrates treated with riboflavin/UV light or untreated controls were analyzed throughout blood bank storage by quantitative proteomics using iTRAQ and puromycin-associated nascent chain (PUNCH) proteomics. RESULTS: Quantitative proteomic analysis identified 408 individual proteins including 26 unique proteins that changed in the treated arm during storage. Proteomic results were confirmed using immunoblot analyses and results suggested a translational control of the protein expression profile. PUNCH proteomic analysis of day 7 samples from illuminated units identified 52 unique platelet proteins that incorporated puromycin, including proteins involved in the cytoskeleton, metabolism, and signaling. CONCLUSION AND CLINICAL RELEVANCE: This study demonstrates for the first time that platelets can synthesize proteins despite the riboflavin and UV treatment and suggests that platelets may possess a mechanism to protect their mRNA from damage by the PI treatment.

Optimization of platelet concentrate quality: application of proteomic technologies to donor management.

Quality management of blood products is essential for blood banking. It is influenced by both processing and donor characteristics and assured by monitoring routine in vitro parameters to defined product specifications. However, these measures correlate poorly with the in vivo behavior of transfused platelets and cannot be used to select optimal donors. Since radiolabeled platelet recovery and survival studies are expensive and time consuming, there is an ongoing search for simpler measures that predict platelet transfusion outcomes. We performed a pilot study using semi-qualitative proteomics to assess changes in the platelet protein profile of donors with either acceptable or unacceptable in vivo radiolabeled autologous platelet recovery and survival measurements. Proteins changing during a 9-day storage period included cytoskeletal elements talin, vinculin and moesin as well as signal transduction proteins 14-3-3, RhoGDI and Rap1. Two of nine donations exhibited a decrease in these proteins and poor in vivo platelet recovery and survival whereas the remaining donors showed acceptable platelet recovery and survival and expected protein profiles. Analyses revealed a significant correlation between protein levels of Rap1 and RhoGDI during storage and platelet recovery and survival. This study provides for the first time preliminary data showing evidence of the utility of protein profiling to predict platelet transfusion quality. This article is part of a Special Issue entitled: Integrated omics.