Monitoring of platelet morphology during storage of platelet concentrates

During storage, human platelet concentrates progressively lose the capacity to survive and function in vivo after transfusion. A shape transformation from disc to sphere is the most reliable in vitro determinant for the loss of the in vivo survival of platelets. To find an objective measurement for platelet morphology, we studied the effect of anticoagulant, temperature, and storage on the apparent median platelet volume (MPV) as determined by a particle counter and on changes in platelet shape as measured and by light microscopy. Changes in MPV, light transmission, and morphology score by light microscopy were observed within 1 minute after collection of blood in CPDA. As compared to blood immediately fixed on withdrawal, in CPDA blood, the MPV increased from 4.1 to 5.7 fl, and light transmission difference decreased from 22 to 7 percent. A partial restoration of these determinants was found when the whole blood was incubated for 30 minutes at 37 degrees C, before preparation of platelet-rich plasma. In the first 5 days of platelet storage, the MPV increased from 4.6 to 5.0 fl; thereafter, it started to decrease. An increase in fragmented platelets after 5 days was observed on light microscopy. The light transmission difference showed a slow disc-to-sphere transformation during storage. This transformation accelerated from Day 5 to Day 7; after 11 days, only spheres were detected. After 7 days the swirling pattern scores were still in accordance with the presence of discs, whereas the other structure-associated determinants showed already spheric and even fragmented platelets.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ammonia accumulation in platelet concentrates during storage

Newly prepared platelet concentrates (PC) and platelet poor plasma (PPP) stored at either room temperature (RT) or 4 C were analyzed for ammonia content initially, and after storage at 24, 48, and 72 hours. These studies demonstrate that ammonia rapidly accumulates in PC stored at RT. This accumulation appears to be temperature dependent, as evidenced by the observed differences in ammonia accumulation in PC stored at 4 C and RT. Whether ammonia acts as a toxic metabolite in the inhibition of platelet function and the development of the "storage lesion," which occurs in PC stored at RT, needs further clarification. Additional studies are also necessary to establish the clinical efficacy of transfusing ammonia-containing platelet concentrates into premature neonates with immature functioning livers, and perhaps into adults with severe liver disease.     

Effect of platelet activation inhibitors on the loss of glycoprotein Ib during storage of platelet concentrates

Platelet membrane glycoprotein Ib (GPIb) in stored platelet concentrates was analyzed by flow cytometry with three separate monoclonal antibodies (AN-51, 6D1, and SZ-2), by tritiated glycoprotein radiolabeling, and by ristocetin-induced agglutination. Flow cytometry showed that a population of surface GPIb-negative platelets was evident at 5 days and increased three- to fivefold by the tenth day. Tritium radiolabeling of surface GPIb showed a decrease over 10 days of 37% +/- 17%. The degree of loss of surface GPIb correlated well with other changes during storage: decreased ristocetin-induced agglutination, decreased responsiveness in the hypotonic shock test, lower plasma pH, and increased extracellular lactic dehydrogenase. Immunoblotting of total platelet GPIb with the SZ-2 antibody showed a decrease of 58% +/- 16% during the 10-day storage period. The effect of protease inhibitors or platelet activation inhibitors on the loss of GPIb during storage was studied in platelet concentrates paired with untreated controls. Only the platelet activation inhibitors prostaglandin E1 and theophylline retarded the loss of surface GPIb levels (93% +/- 5% GPIb remaining vs 65% +/- 16%). Total GPIb levels also decreased less in the presence of the activation inhibitors (45% +/- 22% lost vs 70% +/- 14% lost). These findings suggest that platelet activation, rather than plasma enzymatic activity, is responsible for the loss of platelet GPIb during storage of platelet concentrates.     

Markers of platelet activation and apoptosis during storage of apheresis- and buffy coat-derived platelet concentrates for 7 days

BACKGROUND: The different production methods for platelet concentrates (PCs) result in products with variable in vitro quality and in vivo viability. The aim of this study was to compare in vitro variables of PCs produced by apheresis (AP-PC) or the buffy coat (BC-PC) method by applying a number of new and established assays.
STUDY DESIGN AND METHODS: Standard TRIMA Accel (Gambro BCT) AP-PCs (n = 20) and BC-PCs (n = 20) were stored in 100 percent plasma and changes in mitochondrial membrane potential (ΔΨ_m) were assessed using 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethlybenzimidazolcarbocyanine iodide (JC-1) dye on Days 1, 3, 5, and 7. The capacity of platelets (PLTs) for oxidative phosphorylation was also monitored by measuring oxygen consumption using a Clark-type electrode. PLT viability was measured using a new assay that utilizes the vital stains calcein-AM and FM4-64. Expression of phosphatidylserine (PS), CD42b, CD47, CD61, and CD62P was also assessed.
RESULTS: Although the JC-1 ratio (FL2/FL1) decreased significantly in both preparations, the percentage of PLTs with depolarized ΔΨ_m increased significantly in BC-PCs but not in AP-PCs. However, no significant change was detected in the PLTs' ability to consume oxygen in both preparations. PLTs in BC-PCs also showed significantly lower GPIb, CD47, and CD61 expression than AP-PCs on Day 1. PLTs in both preparations, however, showed a similar increase in CD62P and PS expression during storage, without significant loss of viability.
CONCLUSIONS: PLTs in AP-PCs and BC-PCs undergo different degrees of deterioration in mitochondrial integrity and thus may undergo different degrees of apoptosis. Interventions that maintain mitochondrial integrity may improve PLT viability in vitro.     

Profiling of alterations in platelet proteins during storage of platelet concentrates

BACKGROUND: The quality of platelet concentrates (PCs) is primarily determined in vitro by selective methods (e.g., pH, aggregometry), which provide only limited information on certain platelet (PLT) characteristics. In contrast, proteomic technologies provide a comprehensive overview of the PLT proteome. High interassay variability, however, limits meaningful assessment of samples taken from the same product over time or before and after processing. STUDY DESIGN AND METHODS: Differential in-gel electrophoresis (DIGE) and mass spectrometry were applied to analyze changes in the PLT proteome during storage of PCs. RESULTS: DIGE provides a comprehensive and reproducible overview of the cytoplasmic PLT proteome (median standard deviation of protein spot intensities, 5%-9%). Although 97 percent of cytosolic PLT proteins remained unchanged over a 9-day storage period, septin 2 showed characteristic alterations that preceded by several days more widespread alterations affecting numerous other proteins. Also beta-actin and gelsolin are potential marker proteins for changes in the PLT proteome. Interestingly septin 2 and gelsolin are affected during apoptosis, indicating that apoptosis in PCs may have an impact on PLT storage. CONCLUSION: DIGE is a tool for comprehensively assessing the impact of storage on the global proteome profile of therapeutic PCs. Most of the changes detected are in high-abundance PLT proteins.     

Alterations in glutathione during storage of human platelet concentrates

Glutathione and glutathione disulfide decline rapidly and progressively in human platelet concentrates stored for up to 7 days at 22 degrees C. Total glutathione declines progressively throughout the storage period, with an estimated half-disappearance time of 2 days. Glutathione disulfide remains constant during the first 2 days of storage but declines progressively thereafter, with an estimated half-disappearance time of 3.2 days. Based on measurements of glutathione disulfide in freshly collected platelets, the authors postulate that glutathione disulfide is elevated during the production of platelet concentrates or during the first 2 days of storage, accounting for the lag in its decay curve. Since total glutathione decreases more rapidly than glutathione disulfide, the fraction of glutathione present in the oxidized form increases throughout the storage period. Glutathione-dependent mechanisms maintain essential cell proteins in the appropriate redox states and provide avenues for the detoxification of potentially noxious compounds generated by the cell or within its environment. Changes in platelet glutathione and glutathione disulfide during storage may be responsible for storage-dependent alterations in in vitro functions and may also affect subsequent in vivo recovery and survival upon reinfusion.     

Analysis of the priming activity of lipids generated during routine storage of platelet concentrates

BACKGROUND: Compounds generated during the routine storage of platelet concentrates may have deleterious effects on the transfusion recipient. STUDY DESIGN and METHODS: Daily plasma samples from platelet concentrates, both apheresis platelets and those separated from whole blood, were obtained serially during routine storage. These plasma samples were assayed for their ability to prime the NADPH oxidase in isolated human neutrophils. Quantitative and qualitative analysis of the priming agents was completed by lipid extraction, high-pressure liquid chromatography separation, and gas chromatography/mass spectroscopy. RESULTS: Compounds were generated in both apheresis and whole-blood platelets that significantly primed the NADPH oxidase after 24 and 48 hours of storage, respectively. The priming activity was maximal by component outdate: 2.6-fold that of the buffer-treated control neutrophils (apheresis) and 3.9-fold that of the buffer-treated control neutrophils (whole blood). These agents were generated by cellular constituents, as stored plasma did not demonstrate such priming activity. Inhibition of this priming activity by WEB 2170, a specific platelet-activating factor receptor antagonist, suggested that the observed priming involved the platelet-activating factor receptor. A portion of the priming activity from platelet concentrates was organically extractable: 69 percent of that from apheresis platelets and 46 percent of that from whole-blood platelets. Further purification of the lipid's priming activity by normal-phase high-pressure liquid chromatography demonstrated a single peak of priming activity at the retention time of lysophosphatidylcholines. Because 46 percent of the priming activity from whole-blood platelets was chloroform insoluble and because it has been reported that interleukin 8 is generated during routine storage of whole-blood platelets, the effects of interleukin 8 on the NADPH oxidase were examined. Recombinant monocyte interleukin 8 rapidly primed the oxidase but was not inhibited by WEB 2170. CONCLUSION: Lipids were generated during the routine storage of platelet concentrates that prime the NADPH oxidase, and they may play a role in the severe complications of transfusion therapy. Other non- lipid compounds, such as interleukin 8, that are generated in whole- blood platelets may also contribute to the observed priming activity of plasma.     

Preparation and storage of platelet concentrates

A technique of platelet concentrate preparation and storage is presented which permits the maximum number of viable and functional platelets to be preserved for periods of 72 hours. Although the storage conditions must be followed precisely, the method is nevertheless simple to perform and does not require specialized expensive equipment. Critical factors include: 1) preparation of the platelet concentrates with an initial centrifugation of 1000 × g for 9 minutes and a second centrifugation of 3000 × g for 20 minutes (86%+/− 1 platelet yield), 2) a storage bag composed of either Fenwal's PL-146 or McGaw plastic, 3) constant gentle mixing, 4) a 70 ml residual plasma volume, and 5) room temperature storage (22 C +/− 2). In Vivo platelet recovery after 72 hours of storage at room temperature averaged 46 per cent +/− 3 and survival was 7.9 days +/− 0.3 (81% of fresh platelet viability). The function of these platelets as measured by the correlation between bleeding time and platelet count after transfusion of pooled platelets into unimmunized, aplastic thrombocytopenic recipients was as good as that of fresh platelets. Both viability and function of concentrated platelets stored at 4 C are severely compromised.     

Plasma levels of ionized and total calcium during storage of citrated platelet concentrate

Measurements of ionized and total calcium levels in supernatant plasma samples from citrated platelet concentrates (PCs) were made over 7 days of storage. Both ionized and total calcium increased significantly during the storage period: respectively, from 0.074 mM Ca2+ in fresh platelet-rich plasma to 0.084 mM in PCs stored for 7 days (p = 0.017), and from 1.94 mM total calcium to 2.06 mM (p = 0.014) over the same period. The increase in calcium was partially blocked by the addition of platelet activation inhibitors to the PCs. Platelet-poor plasma stored under similar conditions showed no significant change in ionized or total calcium, which indicated that the increases observed in PCs were due to the release of cellular calcium. Significant correlations (p less than 0.01) were found between ionized or total calcium levels and lactate concentration or pH, but not hypotonic shock recovery rate. The demonstration of non-zero levels of ionized calcium makes it likely that Ca2+-dependent enzyme systems such as calpain expression and thrombin generation are active in the plasma of citrated PCs and may contribute to the platelet storage lesion.     

Five-day storage of platelet concentrates

The short 72-hour shelf-life of platelet concentrates stored in standard PL146 (Fenwal) plastic bags often results in shortages of platelets. This 3-day limitation is based on the biochemical and physiological changes that occur during storage and that result in decreased viability and survival after transfusion. We assessed both in vitro and in vivo function of platelet concentrates stored for 3 and 5 days in two new plastic packs: PL732 (Fenwal) and CLX (Cutter). The concentrate pH was maintained above 7.0 in both bags and there was little change in platelet count or size following 5 days of storage. Aggregation response to adenosine diphosphate, epinephrine, and collagen was maintained well. The PCO2 values indicated good gas escape with lower values after 5 days of storage than at 0 time. Lactate accumulation and glucose utilization were also lower in these new bags. Autologous survivals of chromium-labeled platelets stored for 5 days were 6.0 days (PL732) and 5.1 days (CLX), which are equal to or better than those found for platelets stored for 3 days in PL146. Posttransfusion increments in thrombocytopenic patients were acceptable; 49 percent after 1 hour and 31 percent after 24 hours for concentrates stored in CLX and 44 percent after 1 hour and 28 percent after 24 hours for concentrates stored in PL732. Both of these new bags, which contain different types of plasticizers, provide an environment that results in an improved product and will permit 5-day storage of platelet concentrates; these two benefits will help to alleviate the difficulties in supply of platelet concentrates.     

Platelet adenine nucleotide levels during room-temperature storage of platelet concentrates

Platelet adenine nucleotide levels were measured in freshly prepared platelet concentrates and daily during storage at room temperature. Marked depletions in platelet adenosine triphosphate (ATP) and adenosine diphosphate (ADP) levels were associated with decrease in both plasma glucose levels and poststorage pH. In those concentrates with only moderate glucose consumption, platelet ATP and ADP levels were well preserved and the plasma pH remained above 6.0. The rate of glucose utilization and poststorage pH were greatly influenced by the concentration of contaminating leukocytes. These studies indicate that the rate of exogenous glucose consumption is an important factor affecting platelet adenine nucleotide levels during room temperature storage of platelet concentrates.     

Thrombin receptor levels in platelet concentrates during storage and their impact on platelet functionality

BACKGROUND: Quality control of platelet (PLT) concentrates is challenging, due to PLT lesions, which are difficult to detect with routine methods. The search for reliable PLT lesion biomarkers is focused on the role of PLTs in primary hemostasis. PLT transfusions also have a significant impact on secondary hemostasis. In this phase, responsiveness of PLTs to small amounts of thrombin is crucial. PAR1 and PAR4 are protease‐activated receptors and are responsible for thrombin reactivity of human PLTs. This study should elucidate if levels of those two receptors are changing in PLT concentrates during storage and if those changes have an impact on PLT aggregation and support of thrombin generation. STUDY DESIGN AND METHODS: PLT concentrates from buffy coat preparations were stored in SSP+ solution for 9 days at 22 ± 2°C on a horizontal flatbed agitator, and samples were taken daily for analysis. PAR1 and PAR4 levels were evaluated using Western blot analysis. PLT aggregation was measured using Born aggregometry and specific PAR1 or PAR4 agonists. Thrombin generation was measured using calibrated automated thrombography. RESULTS: Levels of both receptors (PAR1 and PAR4) started to decrease after 5 days of storage. PAR1‐mediated PLT aggregation remained constant, whereas PAR4‐mediated PLT aggregation decreased with storage time. Rate of thrombin generation was accelerated after 5 days of storage. CONCLUSION: Decreasing levels of PARs in PLT concentrates after 5 days of storage influenced PAR4‐mediated, but not PAR1‐mediated, aggregation. Thrombin generation with senescent PLTs was increased, which may be attributed to other mechanisms promoting increased phosphatidylserine exposure.     

Cytokine accumulation in photochemically treated and gamma-irradiated platelet concentrates during storage

BACKGROUND: Photochemical treatment (PCT) for pathogen reduction of platelet concentrates (PCs) affects all cells containing DNA and/or RNA. Soluble mediators, which may cause transfusion reactions, are determined by the balance between secretion and/or cell destruction and binding and/or degradation. STUDY DESIGN AND METHODS: Ten double-dose single-donor leukoreduced PCs were split in two identical units. Two study arms were created: Study Arm A consisting of five PCT PCs with corresponding untreated control PCs and Study Arm B consisting of five PCT PCs with corresponding gamma-irradiated control PCs. PCs that had added PAS-III (Intersol) were treated with amotosalen and ultraviolet A light. Corresponding controls PCs, to which PAS-II (T-sol) were added, received no treatment or were gamma-irradiated before storage. Platelet (PLT)-derived (CCL5/RANTES, CXCL4/PF4, CCL3/MIP-1alpha, transforming growth factor [TGF]-beta, CXCL8/interleukin [IL]-8, IL-1beta) as well as white blood cell (WBC)-associated (IL-6, IL-10, IL-11, IL-12, tumor necrosis factor, interferon-gamma) cytokines were investigated by enzyme-linked immunosorbent assay and cytometric bead array during storage for up to 12 days. RESULTS: Independent of previous treatment we observed that all concentrates showed low levels of WBC-associated cytokines. PLT-derived cytokines were detected at higher levels and showed significant increase during storage. Statistical analysis showed lower PLT content per unit in PCT PCs, higher levels of activation variables in PCT PCs, and higher levels and accumulation rate of CCL5, CXCL4, TGF-beta, and CXCL8 in PCT PCs. CONCLUSION: PLTs are the main source of released cytokines during storage of untreated, gamma-irradiated, and PCT PCs. PCT may affect the level of PLT-derived cytokines in PCs. No additional reduction of WBC-associated cytokines were observed after PCT in prestorage leukoreduced PCs.     

Generation of kinins during preparation and storage of whole blood-derived platelet concentrates

BACKGROUND: Leukoreduction of platelet (PLT) concentrates (PCs) may be associated with hypotension in recipients, and a role for bradykinin (BK)-related peptides has been proposed for this side effect. STUDY DESIGN AND METHODS: The concentration of BK and one of its vasoactive metabolites, des-arginine(9)-BK (des-Arg(9)-BK), was measured in a large number of PCs as a function of leukoreduction and storage duration with specific enzyme immunoassays and complementary techniques. RESULTS: On Day 0 of storage, kinins were detected in leukoreduced and unfiltered PCs at a concentration lower than 100 pg per mL. During storage, both kinin levels peaked on Day 5 of storage, with a concentration higher than 1 ng per mL in 22 percent of PCs whether filtered on Day 0 or not. Physicochemical and pharmacologic characterizations of immunoreactive kinins confirm their nature. In vitro activation of the contact system of the corresponding PLT-poor plasma showed that a high kinin concentration on Day 5 of the storage corresponded with a low kinin-forming capacity of plasma. On Day 7, BK was no longer elevated presumably due to its degradation and the depletion of kinin-forming capacity of the plasma in stored PCs. The activities of metallopeptidases that metabolize BK-related peptides in plasma from PCs were at levels similar to those recorded in the plasma of a normal reference population and were unaffected by storage. CONCLUSION: Storage of PCs contributes to the hydrolysis of high-molecular-weight kininogen and generation of pharmacologically relevant BK levels that might pose a hazard in susceptible patients.     

Platelet membrane glycoprotein changes during the preparation and storage of platelet concentrates

Previous studies of platelet membrane glycoproteins during blood bank storage have reported conflicting results. This study assessed two major plasma membrane glycoproteins (GP Ib and GP IIb), an alpha-granule membrane protein (GMP-140), and the concentration of platelet membrane microparticles in cell-free plasma during routine hospital blood bank platelet storage. 125I-monoclonal antibody binding was used to measure membrane glycoproteins on the surface of intact platelets and to measure the concentration of membrane microparticles in cell-free plasma. Platelet concentrates were stored at room temperature in polyolefin bags for 7 days. In this blood bank, two types of rotators are routinely used for platelet concentrate storage: a 2-rpm circular tumbler rotator and a 6-rpm elliptical rotator. Different results were obtained with the rotators. With the tumbler rotator, there was no loss of platelets and antibody binding to GP Ib remained normal. With the elliptical rotator, one third of platelets were lost into clumps during storage, and a 50 percent decrease of antibody binding to GP Ib occurred in the remaining single platelets. There was no loss of antibody binding to GP IIb with either rotator. Antibody binding to GMP-140 increased equally in both rotators indicating that the remaining single platelets had secreted about 16 percent of their alpha-granule contents. The plasma concentration of platelet membrane microparticles was greater in the bags stored in the elliptical rotator. These results indicate that it is possible to maintain the normal concentration of platelet membrane glycoproteins Ib and IIb during 7 days of room-temperature blood bank storage.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multiple pH measurement during storage may detect bacterially contaminated platelet concentrates

BACKGROUND: Bacterial contamination or platelet (PLT) metabolism can change the pH of stored PLT concentrates (PCs). Measurement of pH for quality control is currently done on a limited basis. An easy noninvasive method was developed to obtain sequential pH measurements over time, without risking contamination and/or consuming PCs. STUDY DESIGN AND METHODS: The objective was to measure pH profiles of bacterially contaminated PCs over 7 days of storage. Small‐volume PC storage bags with incorporated pH sensor were prepared and in vitro variables were tested using aliquots of PCs. The pH sensors were used to delineate trends associated with the deterioration of these PCs upon inoculation with 19 different bacterial strains and one yeast. RESULTS: Monitoring the pH trends in real time in a noninvasive fashion, most bacterial strains were detected within 24 to 72 hours after spiking into the bag. At the time of detection, bacterial concentrations had reached levels between 1 × 10³ and 1 × 10⁸ colony‐forming units/mL. Several strains had pH rebound after initial drop. Multiple noninvasive pH reads allowed bacterial detection whereas single pH reads could give false‐negative results. CONCLUSIONS: The noninvasive pH sensor facilitated the detection of most strains of bacterial contaminants within 3 days with no potential for sampling error.