The effect of near-infrared low-level light on the in vitro quality of platelets during storage.

BACKGROUND AND OBJECTIVES: Near-infrared (NIR) light has been successfully applied to improve the quality of mouse platelets during storage. Because it is suspected that the mitochondria contain the primary photon acceptor, we hypothesized that human platelets for transfusion may be affected similarly and could benefit from NIR light treatment. MATERIALS AND METHODS: The optimal light dose was determined using portions of platelet concentrates (PCs) in PAS-E. A pool-and-split design was used to prepare PCs in PAS-E or plasma (n = 6). On day 1, one unit of both pairs was illuminated with 830 nm light (light-emitting diodes, 15 J/cm2). PCs were stored at 22°C and sampled regularly for analysis. Data were compared with their corresponding controls with a paired two-sided t-test. RESULTS: Illuminated platelets in PAS-E were less activated with significantly lower CD62P expression (day 8: 10.8 ± 1.8 vs. 12.2 ± 2.6, p < 0.05) and lower Annexin A5 binding (day 8: 11.8 ± 1.9 vs. 13.1 ± 2.4, ns). They produced significantly less lactate resulting in a higher pH (days 6-10). ATP content and mitochondrial membrane potential were not affected. Although these trends were also observed for PCs in plasma, the differences did not reach statistical significance as compared with the control group. CONCLUSION: Our study demonstrates that the glycolysis rate of human platelets can be modulated through the use of NIR, possibly through mitochondrial aerobic metabolism, but this requires confirmation. If NIR illumination can be further optimized, it may potentially become a useful tool in situations in which glycolysis and platelet activation are exacerbated.

Donor variation in stored platelets: Higher metabolic rates of platelets are associated with mean platelet volume, activation and donor health.

BACKGROUND: Platelets (PLTs) differ in glycolytic activity, resulting in rapid acidification of 'poor' storing PLT concentrates (PCs) in plasma, or depletion of glucose when stored in PLT additive solution (PAS). We aimed to understand why PLT glycolysis rates vary between donors and how this affects storage performance. STUDY DESIGN AND METHODS: Buffy coats from donors <45, 45-70 and >70 years were selected and single-donor PCs in plasma or PAS-E were prepared. PCs were stored for 8 days at 22 ± 2°C and sampled regularly for analysis. Mitochondrial activity was analyzed with an Oroboros oxygraph. Age groups, or subgroups divided into quartiles based on glucose consumption, were analyzed with ANOVA. RESULTS: In each comparison, PCs of the different groups were not different in volume and cellular composition. PLTs with the highest glucose consumption had a higher initial mean platelet volume (MPV) and developed higher CD62P expression and Annexin A5 binding during storage. Higher glycolytic activity in these PLTs was not a compensation for lower mitochondrial ATP production, because mitochondrial ATP-linked respiration of fresh PLTs correlated positively with MPV (R2  = 0.71). Donors of high glucose-consuming PLTs had more health-related issues. Storage properties of PCs from donors over 70 were not significantly different compared to PCs from donors younger than 45 years. CONCLUSIONS: High glucose-consuming PCs developing higher activation levels, not only displayed enhanced mitochondrial activity but were also found to contain larger PLTs, as determined by MPV. Storage performance of PLTs was found to be associated with donor health, but not with donor age.

Evaluation of platelet concentrates prepared from whole blood donations with collection times between 12 and 15 min: The BEST Collaborative study.

BACKGROUND AND OBJECTIVES: In many countries, whole blood (WB) donations with collection times between 12 and 15 min are not allowed to be used for platelet concentrates (PC). Since the development of guidelines, many process-related changes have been introduced. We aimed to determine the effect of WB with long collection times on PC quality. MATERIALS AND METHODS: Five participating centres tested buffy coat (BC)-derived PC in platelet additive solution type E prepared from only WB collections lasting <12 min (control) versus similar PC including one BC from a collection lasting >12 min (study group, n = 8). One centre produced platelet-rich plasma (PRP)-derived PC from single donations (<10 or >12 min). All PC were stored at 22 ± 2°C and sampled on Days 1, 6 and 8 post-collection for in vitro quality determination. RESULTS: Average collection time was significantly longer in the study group compared to controls (8.9 ± 2.6 vs. 7.3 ± 1.3 min, p < 0.001). There were no differences in volume, platelet concentration, basal CD62P expression, soluble-CD62P and CCL5 levels, or nucleotide content between the groups. Stimulation with TRAP-6 resulted in comparable levels of cell surface CD62P. On Day 8, all PC fulfilled requirements for pH. The findings from single PRP-derived PC centre were similar. CONCLUSION: PC with one BC and single PRP derived from collections lasting >12 min had equivalent in vitro quality to controls during storage. This study provides evidence that 12-15 min donations should not be excluded for PC preparation and justifies to readdress the guidelines to <15 min instead of <12 min of collection in line with current practice in some countries.

Thromboelastography as a tool to evaluate blood of healthy volunteers and blood component quality: a review.

Thromboelastography is a technique to evaluate the overall coagulation behaviour of blood and blood components. First, we evaluated the literature concerning the use of thromboelastography for characterizing coagulation behaviour of healthy volunteers, such as blood donors. Overall coagulation is sensitive to gender, most likely caused by the difference in haematocrit and plasma content of male versus female blood. Smaller and less pronounced effects in thromboelastographic response are caused by differences in fibrinogen level or by use of oral contraceptives. Short-term hypercoagulable effects are observed after smoking or blood donation, while small effects of non-steroidal anti-inflammatory drugs on platelets are also present. Second, in whole blood donations, the thromboelastographic variables are also sensitive to storage time and temperature, but are less sensitive to levels of clotting factors. Platelet count and quality have little influence on thromboelastographic variables, and differences are mainly observed at counts <100x109 /l, after extended storage time of platelet concentrates or storage under specific conditions, including freezing. Thromboelastographic profiles of plasma samples are mainly affected by residual cell counts, microparticles and fibrinogen levels, and less by levels of clotting factors. Taken together, publications have shown that as an overall clotting test, thromboelastography may support optimization of blood component preparation and storage with regard to temperature, time and secondary and tertiary treatments. Minimal deviations of in vitro quality are most reliable demonstrated when an appropriate assay is chosen.

Platelet storage properties are associated with donor age: in vitro quality of platelets from young donors and older donors with and without Type 2 diabetes.

BACKGROUND AND OBJECTIVES: Previously it has been shown that platelet (PLT) storage performance is consistent by donor. Differences involved metabolic activity, which might be caused by mitochondrial (dys)function, associated with age and age-related diseases like Type 2 diabetes (T2D). We aimed to test PLTs from young donors in comparison with PLTs from older donors with or without diagnosis for T2D. MATERIALS AND METHODS: Fifteen whole blood donors <30 year were selected, and single-donor platelet concentrates (sPC) were prepared from buffy coats (BC) and plasma. Also, 2 × 11 sPC were prepared from matched donors >45 years with and without T2D. The sPC were stored for 8 days and analysed at regular intervals for in vitro quality. RESULTS: Donors were 24 ± 3, 60 ± 7 (without T2D) and 59 ± 8 (with T2D) years old. All sPC groups had comparable volume and PLT content. On Day 8, sPC from young donors showed higher pH37°C than sPC from older donors (6.84 ± 0.15 vs. 6.40 ± 0.48, P < 0.01), due to lower lactate production. Also, CD62P expression (22.9 ± 7.4 vs. 48.8 ± 24.0%, P < 0.01) and HSR reflected better in vitro quality. PLT storage properties of sPC obtained from T2D donors (pH = 6.51 ± 0.35) were not different from sPC of matched donors (pH = 6.40 ± 0.48). No differences in mitochondrial membrane potential were detected between the groups. CONCLUSION: Platelets from young donors exhibited the best storage conditions. On average, PLTs from older donors showed poorer in vitro quality but, considering the sub-optimal storage conditions, the implications for the daily blood bank routine is probably small. No association with T2D was found.

Platelet storage performance is consistent by donor: a pilot study comparing "good" and "poor" storing platelets.

BACKGROUND: In retrospective studies, it has been shown that differences in storage variables of platelet (PLT) concentrates (PCs) are partially donor dependent. It was our aim to prospectively determine the donor effect on PLT quality. STUDY DESIGN AND METHODS: Based on quality control data of outdated apheresis PCs, male donors were selected with at least one PC with a pH value of more than 7.0 ("good," n = 6) or one PC with a pH value of less than 6.7 ("poor," n = 6) on Day 8. These donors donated a PC (Trima Accel, Terumo) and completed a short questionnaire about their health and lifestyle. PCs were stored for 12 days and analyzed at regular intervals for in vitro quality. RESULTS: Donor characteristics were comparable, except that zero of six good and four of six poor donors reported high blood pressure and/or high cholesterol/fat and/or use of medicines. Lactate production in good PCs was lower than that in poor PCs (0.09 ± 0.03 mmol/day/1011 PLTs vs. 0.13 ± 0.04 mmol/day/1011 PLTs, p < 0.05) resulting in a higher pH from Day 5 onward. At the end of storage, the good PCs showed lower CD62P expression, lower phosphatidylserine exposure, and higher mitochondrial membrane potential. PLT functional properties were only slightly different. Despite having lower pH, the poor PCs also fulfilled European Guidelines during 7-day storage. CONCLUSION: Platelet storage performance is consistent when donors are dichotomized as having good or poor storing PLTs. Metabolic differences are perhaps due to different functionality of the mitochondria. More research is needed to establish the underlying causes and the implications for donors and blood products.

Effect of solvent/detergent-treated pooled plasma on fibrinolysis in reconstituted whole blood.

BACKGROUND: Hyperfibrinolysis has been observed in patients heavily transfused with solvent/detergent-treated pooled plasma (S/D plasma). We compared coagulation and fibrinolytic variables in blood containing S/D plasma with blood containing fresh-frozen plasma (FFP), with and without α2-antiplasmin or tranexamic acid (TXA) supplementation. STUDY DESIGN AND METHODS: Whole blood samples were reconstituted from red blood cells, platelet (PLT) concentrates, and varying mixtures of FFP and S/D plasma. Hematocrit and PLT count of reconstituted whole blood samples were varied. For a subset of runs, α2-antiplasmin or TXA was added to S/D plasma whole blood samples. Thromboelastography (TEG) analysis was performed to assess 50% clot lysis time (CLT50% ), maximum amplitude (MA), and initial clotting time (R-time). RESULTS: The change in CLT50% of whole blood as the plasma compartment transitions from FFP to S/D plasma was -52% (95% confidence interval [CI], -60% to -45%; p < 0.001). PLT count strengthened the effect, leading to an additional change in CLT50% of -8% (95% CI, -14% to -2%; p = 0.012) as PLT count increased from 10 × 109 to 150 × 109 /L. MA and R-time were not associated with fraction of S/D plasma in whole blood. α2-Antiplasmin and TXA restored clot lysis time in S/D plasma whole blood. CONCLUSION: Whole blood with S/D plasma has shorter clot lysis times in vitro compared to whole blood with FFP. α2-Antiplasmin and TXA restore clot lysis time of S/D plasma whole blood to that of FFP whole blood. Clinicians should be aware of the decreased clot lysis time associated with S/D plasma transfusion.

Riboflavin and UV light treatment of platelets: a protective effect of platelet additive solution?

BACKGROUND: Pathogen reduction technologies (PRTs) increase the safety of the blood supply, but are also associated with cell damage. Our aim was to investigate the effect of Mirasol PRT on platelet (PLT) concentrates stored in plasma and whether the use of a PLT additive solution (PAS) is able to improve in vitro quality. STUDY DESIGN AND METHODS: Twenty-two buffy coats (BCs) were pooled and split into two equal parts. To one half, 2 units of plasma were added, and to the other, 2 units of SSP+ PAS were added. Each part was equally split in half again (to resemble pooling five BCs) and PLT concentrates were prepared. One plasma PLT concentrate was Mirasol treated, and the other served as control; similarly, one SSP+ PLT concentrate was Mirasol treated, and the other not. PLT concentrates were stored for 8 days (n = 12). RESULTS: Mirasol PRT led to elevated lactate production in PLT concentrates in plasma, giving lower pH values throughout storage. The use of SSP+ mostly abrogated this effect, and Mirasol-treated PLT concentrates in SSP+ had only slightly higher lactate production rates and annexin A5 binding as control PLT concentrates in plasma. However, irrespective whether plasma or SSP+ was used, Mirasol PRT led to higher CD62P expression and lower hypotonic shock response (HSR) scores. CONCLUSION: Mirasol treatment leads to higher PLT activation and lower HSR scores both when stored in plasma or SSP+. However, if Mirasol-treated PLTs are stored in SSP+, lactate metabolism and annexin A5 binding are lower, showing that PAS can partly mitigate the effect of PRT. The clinical relevance of this finding needs to be demonstrated.

A new preparation method for red blood cells for intrauterine transfusion enabling reduction of donor exposure.

BACKGROUND: Severe hemolytic anemia of the fetus, caused by maternal red blood cell (RBC) alloantibodies, is treated with intrauterine transfusion (IUT) of RBCs. Because IUT is associated with additional antibody formation, RBCs with the closest match between donor and mother are preferred. Because one fetus needs a median of three IUTs, finding such RBCs is complicated. Collection of repeated low-volume donations from one selected donor during the entire IUT treatment period would reduce donor exposure and possibly IUT-associated alloimmunization. STUDY DESIGN AND METHODS: Whole blood (WB) donations of 100 and 200 mL were diluted with saline, filtered, centrifuged, and separated to prepare experimental RBCs. Before and after gamma irradiation, the RBCs were sampled for comparison of in vitro quality with standard RBCs for IUT. An additional washing procedure was investigated to remove anti-A/-B. RESULTS: Experimental RBCs were leukoreduced to levels conforming with current guidelines and had final volumes of 44 (n = 12) and 84 (n = 8) mL with hematocrit levels between 0.80 and 0.88 L/L. Hemolysis was lower (0.12% vs. 0.42%), potassium leakage comparable, adenosine triphosphate levels lower (4.8 µmol/g Hb vs. 6.1 µmol/g Hb), and 2,3-diphosphoglycerate levels higher (10.3 µmol/g Hb vs 7.7 µmol/g Hb) at 6 hours after irradiation (product expiration time) compared to standard RBCs for IUT (n = 3). Anti-A/-B titers decreased substantially by the washing procedure. CONCLUSION: RBCs for IUT can be prepared from 100- or 200-mL WB donations, showing the potential of this new blood product to reduce donor exposure. A washing procedure is recommended to remove anti-A/-B.

Determination of thromboelastographic responsiveness in stored single-donor platelet concentrates.

BACKGROUND: Thromboelastography (TEG) is widely used in hospitals but less commonly in blood banks for evaluation of platelet (PLT) concentrates (PCs). A TEG-PC assay for testing fresh or stored PLTs must reflect the quality of the PLTs. The added value could be measurement of donor-dependent PLT quality. STUDY DESIGN AND METHODS: Whole blood (WB) normal values were generated from 100 donors, using standard tests. Nineteen single-donor PCs were evaluated with a TEG-PC assay, using Octaplas as microparticle-free diluent and kaolin or collagen as activator, stored up to 12 days, and also sampled for additional in vitro tests. RESULTS: WB values showed larger reaction rates (R- and K-times, angle) compared to the reference values and almost similar maximum amplitude (MA). PCs showed usual storage lesion and TEG-PC results showed significant decreasing R- and K-times and increasing angle. Mean MA values remained constant but individual measurements were affected by clot retraction. TEG tracings of two PCs with good quality on Day 12 showed weak to strong clot retraction, while two PCs with poor quality showed moderate clot retraction on Day 1, no clot retraction on Days 5 to 12, and a decreased MA on Day 12. Clot strength (MA) and especially clot retraction represent possibly donor-specific effects. CONCLUSION: A TEG-PC assay has been developed that is sensitive to storage effects. The assay has the potential to be helpful in selection of PLT donors but needs improvement to be more sensitive, reproducible, and distinctive to determine whose PLTs store poorly and whose store well.

Evaluation of the quality of blood components obtained after automated separation of whole blood by a new multiunit processor.

BACKGROUND: The Reveos system (Terumo BCT) is a fully automated device able to process four whole blood (WB) units simultaneously into a plasma unit, a red blood cell (RBC) unit, and an interim platelet (PLT) unit (IPU). Multiple IPUs can be pooled to form a transfusable PLT product. The aim of our study was to evaluate the quality of components made with the Reveos system from either fresh (2-8 hr) or overnight-held WB. STUDY DESIGN AND METHODS: A prototype of the Reveos system was used to process WB. RBCs were resuspended in SAGM, leukoreduced, and assayed for in vitro quality variables during a 42-day storage period at 2 to 6 °C. Twenty-four-hour in vivo recovery was determined on Day 42. Plasma was assayed for cellular contamination and activation variables. IPUs were pooled with SSP+ additive solution for in vitro quality assessments during a 7-day storage period at room temperature. RESULTS: Reveos-produced RBCs and plasma units met the predefined requirements. RBC recovery was superior to control units. On Day 42, hemolysis was below 0.8% and in vivo recovery was above 75% for all RBCs. Cellular contamination was lower for Reveos-produced plasma. PLT yield was higher with overnight-stored WB. PLT quality was well maintained during storage with no significant differences between the two groups. CONCLUSION: Blood components prepared with the Reveos from fresh or overnight-held WB meet quality criteria without any relevant difference between the two groups. The Reveos system has the potential to increase efficacy and standardization of blood component preparation.

Volume-reduced platelet concentrates: optimization of production and storage conditions.

BACKGROUND: Plasma can be removed from platelet (PLT) concentrates (PCs) when volume reduction for PLT transfusion is indicated. Volume-reduced PCs are currently produced from pooled buffy coat (BC) PCs or apheresis PCs by pretransfusion volume reduction, followed by transfer to a syringe for immediate transfusion. We evaluated the maximal storage time of the volume-reduced PCs in gas-permeable containers. STUDY DESIGN AND METHODS: Volume-reduced PCs were produced from BC-derived and apheresis PCs by hard-spin centrifugation. Supernatant was removed and the PLTs were resuspended in 20 mL of retained original PC and had PLT concentrations ranging from 10.8 × 10(9) to 13.8 × 10(9) PLTs/mL. Volume-reduced PCs were stored either in syringes or in containers made from diethylhexyl phthalate (DEHP)-polyvinylchloride (PVC) or butyryl trihexyl citrate (BTHC)-PVC plastic. Units were sampled at t = 0, 1, 3, and 6 hours for in vitro measurements. RESULTS: When prepared from 2-day-old PCs (n = 4), volume-reduced PCs from BCs in a syringe had a pH(37°C) of 5.76 ± 0.04 at t = 6 hours after volume reduction. In the DEHP-PVC container, pH was 5.85 ± 0.15 (not significant), and in the BTHC-PVC, 6.34 ± 0.16 (p < 0.001), at t = 6 hours. When made from 7-day-old PCs, pH was lower for all storage conditions: 5.68 ± 0.06 in the syringe, 5.70 ± 0.09 in the DEHP-PVC container (not significant), and 6.07 ± 0.24 in the BTHC-PVC container (p < 0.01) at t = 6 hours. Volume-reduced 2-day-old apheresis PCs had a pH of 6.47 ± 0.20 at t = 6 hours. CONCLUSIONS: Adult-dose PCs derived from BC or apheresis can be volume-reduced to approximately 20 mL in a closed gas-permeable system. Volume-reduced PCs in BTHC-PVC containers retain a mean pH of more than 6.0 up to 6 hours after production. Syringes allow only 3 hours of storage.