Microparticle sizing by dynamic light scattering in fresh-frozen plasma.

BACKGROUND: We have previously shown that fresh-frozen plasma (FFP) contains red blood cell-derived procoagulant microparticles (MPs) that are removable by 0.2 microm filtration. Given the limitations of current methods for accurately sizing MPs, we have applied the novel approach of dynamic light scattering (DLS) to characterize the size distributions of these MPs within FFP. METHODS: Fresh-frozen plasma was prepared from blood Group A and O donations (n = 10 of each) after an overnight hold of whole blood at 4 degrees C. On the day of analysis, plasma was thawed to 37 degrees C and daughter aliquots were studied pre- and post-filtration (0.2 microm filtration device, Ceveron MFU-500, Technoclone). MP size and dispersity was assessed using a Zetasizer Nano S (Malvern Instruments Ltd), which employs a 173 degrees backscatter detector and an N5 Submicron Particle Size Analyser (Beckman Coulter) using multi-angle measurements (30.1 degrees , 62.6 degrees and 90 degrees ). The analysers presented MP size distribution graphically as intensity plots, mean size, standard deviation and polydispersity index. RESULTS: Of the instruments used, only the N5 utilizing a 30.1 degrees angle of measurement could detect MPs of the expected size distribution and demonstrate their removal by filtration. MPs (range of mean particle diameters: pre, 101-464 nm; post, 21-182 nm filtration) were significantly smaller post-filtration (P < 0.0001), but polydispersity index (median: pre, 0.746, post, 0.769) exhibited no significant change. There was no significant difference between the size of MPs from blood Group O (pre, 247 nm) and Group A (pre, 289 nm) samples (P = 0.44). CONCLUSION: Our data demonstrates that DLS offers a novel approach to assessing MP size and distribution, a technique that could be easily adopted as a means of assessing MPs within either FFP or other blood products.

The dynamics of clot formation in fresh-frozen plasma.

BACKGROUND: Factor VIII (FVIII) levels are used as a quality marker of fresh-frozen plasma (FFP); however, other clotting factors are not routinely measured. METHODS: We assessed additional haemostatic parameters and the dynamics of coagulation using Thrombelastography (TEG) and a thrombin generation test (TGT). FFP was prepared on the day of donation (Day 0) or after overnight hold at 4 degrees C (Day 1). RESULTS: Factor VIII in Day 1 FFP was 18% lower than in Day 0. TEG parameters in Day 1 FFP were consistent with increased coagulability and did not correlate with altered levels of clotting factors, but were consistent with the increased levels of microparticles seen in the Day 1 samples. TGT studies exhibited increased lag time, time to peak and reduced peak thrombin generation, but no change in endogenous thrombin potential (ETP) on Day 1. There was a weak association between FVIII level and both ETP and peak thrombin (ETP r(s)> or = 0.22, P< or = 0.003; peak thrombin r(s)> or = 0.48, P< or = 0.0001), which was influenced by ABO group, with the lowest levels in group O. CONCLUSION: We conclude that levels of FVIII do not predict the haemostatic potential of FFP and that there may be a role for alternative technologies in monitoring the quality of FFP.

The characterization and impact of microparticles on haemostasis within fresh-frozen plasma.

BACKGROUND: We have previously demonstrated that clot formation in fresh-frozen plasma (FFP) is influenced by the presence of microparticles (MP). In this study, the cellular source(s), properties and influence of MPs on clot formation within FFP were further characterized. METHODS: Fresh-frozen plasma was prepared after an overnight hold of whole blood at 4 degrees C. We examined the effect of a 0.2 microm filtration device designed to remove cellular MPs on thrombin generation test (TGT) and Thrombelastography (TEG(R)) as well as clotting factors and physiological inhibitors: prothrombin time (PT); activated partial thromboplastin time (APTT), fibrinogen (Fg), factor VIII (FVIII), von Willebrand factor antigen (VWF:Ag), antithrombin III (AT-III) and protein C (PC). MPs were measured using a functional assay and also by flow cytometry. RESULTS: Microparticle levels by functional assay were reduced by filtration (pre- 5.11 vs. post- 4.43 nmol/l phosphatidylserine equivalent, P < 0.0001). Flow cytometry showed that the most numerous MPs were derived from red blood cells, with ~87% binding annexin V, most of which (94%) were removed by filtration. MP removal had minimal effect on the PT, APTT, Fg, VWF:Ag, AT-III or PC or FVIII, but a major effect on TGT (endogenous thrombin potential: pre- 1722 vs. post- 990 nM thrombin, P < 0.0001; peak thrombin: pre- 91 vs. post- 44 nM thrombin, P < 0.0001), which in turn reflected the changes seen in TEG(R), where post-filtration clots started forming more slowly and the rate of clot formation was reduced. CONCLUSION: These data suggest that MPs contribute towards clot formation in FFP.

Plasma levels of factor XIIa and factor VIIa are increased but not related in primary hyperlipidaemia.

The lipolysis of triglyceride-rich lipoproteins may provide a surface that supports the activation of factor XII (FXII) with subsequent activation of factor VII (FVII). Plasma levels of activated FVII (FVIIa) but not activated FXII (FXIIa) are increased in the post-prandial state when there is a transient increase in triglyceride levels. We compared plasma levels of FXIIa antigen in control subjects (n = 33) and in patients with chronically elevated lipids (primary hyperlipidaemia, n = 49), with FVIIa and markers of thrombin generation. Results are given as median (first and third quartiles). Plasma levels of FXIIa [2.34 (1.68-3.32) ng/ml versus 1.53 (0.93-1.86) ng/ml, P = 0.0002], FVIIa [3.02 (2.15-4.64) ng/ml versus 2.20 (1.66-2.56) ng/ml, P = 0.0004], thrombin-antithrombin complexes [3.08 (2.16-5.54) microg/I versus 2.13 (1.46-2.84) microg/l, P = 0.005] and prothrombin fragment 1 + 2 (Pro F1 + 2) [1.28 (1.08-1.50) nmol/l versus 0.92 (0.65-1.08) nmol/l, P = 0.0001] were increased compared with controls irrespective of the type of hyperlipidaemia. In hyperlipdaemic subjects, levels of Pro F1 + 2 were correlated with FVIIa (r = 0.56, P = 0.0002) and FXIIa (r = 0.31, P = 0.03). These results suggest increased activation of both FVII and FXII in hyperlipidaemic subjects, which correlates with increased thrombin generation. Given the lack of correlation between levels of FXIIa and FVIIa, it remains to be established whether the increase in FXIIa is responsible for increased FVIIa activity in this subject group.

Determination of plasma aprotinin levels by functional and immunologic assays.

We compared a functional (amidolytic) and an enzyme-linked immunosorbent assay (ELISA) method for determining aprotinin concentration in 82 plasma samples obtained from patients undergoing cardiac surgery with aprotinin therapy. There was good correlation between methods (r = 0.87); however, aprotinin measurements by chromogenic assay were significantly higher than by ELISA [234 +/- 104 kallikrein inhibitory units (KIU)/ml versus 155 +/- 88 KIU/ml; P = 0.0001]. This appeared to be attributable to differences in the potency of the material used to standardize the assays. When results were corrected to allow for potency of the standard, there was no significant difference between chromogenic and ELISA methods (234 +/- 104 KIU/ml versus 240 +/- 137 KIU/ ml), although the ELISA results tended to be higher in some samples. These data suggest that aprotinin concentrations measured by these methods cannot be used interchangeably, and care must be taken when interpreting data from studies measuring aprotinin.

Activation of the tissue factor pathway occurs during continuous venovenous hemofiltration.

BACKGROUND: Activation of the tissue factor pathway occurs during continuous venovenous hemofiltration (CVVH). Despite adequate exogenous anticoagulation, the occlusion of CVVH circuits can occur within minutes to a few hours of use and is associated with evidence of thrombin generation. Having found no evidence of activation of the contact factor (intrinsic coagulation) pathway during CVVH, we sought to examine the effect of the first episode of CVVH on the tissue factor (extrinsic) pathway of coagulation and thrombin generation. METHODS: Twelve critically ill patients were studied prior to the commencement of hemofiltration and at regular intervals thereafter until the filter clotted. RESULTS: Prior to hemofiltration, most patients had increased levels of plasma tissue factor, thrombin-antithrombin (TAT) complexes, and tissue factor pathway inhibitor (TFPI); during hemofiltration, further generation of TAT complexes occurred. Initially, levels of activated factor VII (FVIIa) fell and TFPI increased, but during the course of hemofiltration, the levels of TFPI fell and FVIIa increased. Levels of tissue factor increased during CVVH in some patients, but this was not related to the generation of FVIIa. CONCLUSIONS: These data indicate that activation of FVII occurred during CVVH, which was related to levels of TFPI, but not tissue factor, and was coincidental to thrombin generation.

The association of factor VIIa, factor XIIa and beta2-glycoprotein-1 with triglyceride-rich lipoproteins in normolipidaemic subjects.

The activation of factors XII (FXII) and VII (FVII) has been shown to occur on the surface of lipoproteins in the presence of lipoprotein lipase and may be modulated by beta2glycoprotein-1 (beta2GP1). In the postprandial state FVII is activated without apparent activation of FXII in plasma. We investigated whether beta2GP1, FXIIa and FVIIa are associated with triglyceride-rich lipoproteins in the fasting and postprandial state. Six normal subjects were studied while fasting and 1, 2 and 4 h after ingestion of 100 g fat. We confirmed that plasma FVIIa activity, but not FXIIa antigen, was increased in the postprandial period. FXIIa, FVIIa and beta2GP1 were associated with chylomicra-rich lipoproteins, and lipase or Triton X-100 treatment caused an increase in FXIIa in plasma and chylomicra without an increase in FVIIa. This suggests that FXIIa may be formed in the postprandial period, but its antigenic determinants are masked by the association with lipoprotein particles, although it could still express proteolytic activity. Alternatively a FXII-independent mechanism or surface other than triglyceride-rich lipoproteins may be responsible for FVII activation in the postprandial state.

Relationship between preoperative endotoxin immune status, gut perfusion, and outcome from cardiac valve replacement surgery.

STUDY OBJECTIVE: Endotoxin is a powerful trigger of systemic inflammation. Since cardiac surgery exposes patients to endotoxemia, this study was set up to define the relationship between preoperative endogenous endotoxin immune status, gut perfusion, and outcome following cardiac valve replacement surgery. DESIGN: Observational study. SETTING: University hospital. PATIENTS: Fifty-nine consecutive patients undergoing cardiac valve replacement. MEASUREMENTS AND MAIN RESULTS: Blood was assayed for IgG and IgM endotoxin core antibody (EndoCAb) levels preoperatively, immediately postoperatively, and at 4 h and 24 h postoperatively. Intraoperative gut mucosal perfusion was assessed using gastric tonometry. Complications were assessed for groups above and below the median EndoCAb value of a healthy population (100 median units micro/mL). Of the 59 patients, 12 developed at least one of a set of predefined complications. Of these 12, all had preoperative levels of IgM EndoCAb below 100 MU/mL (p<0.025). Eleven had IgG EndoCAb levels below 100 MU/mL (0.05

Hemostatic-endothelial interactions: a potential anticoagulant role of the endothelium in the pulmonary circulation during cardiac surgery.

The use of extracorporeal circulation during cardiopulmonary bypass (CPB) procedures is associated with significant morbidity and mortality. Exposure of blood to the foreign surface of the extracorporeal circuit results in activation of complement, kinin, fibrinolytic and coagulation systems as well as cellular mediators of inflammation. Without the use of anticoagulants, the extracorporeal circuit would clot; high-dose heparin prevents coagulation, but activation of the coagulation system and consequent thrombin generation still occur. During CPB, the lungs are effectively removed from the circulation, and, hence, heparinized blood remains static within the pulmonary vasculature for this period. It was postulated that under these conditions, the hemostatic system may become activated and could contribute to pulmonary dysfunction in some patients after CPB. However, it appears that during CPB interactions among heparin, the hemostatic system, and the endothelium may exert a protective effect, at least against activation of the tissue factor coagulation pathway. In this article, the effect of CPB on the coagulation system, with particular reference to changes in coagulation proteins occurring in the pulmonary vasculature, are reviewed.

Maintenance of therapeutic plasma aprotinin levels during prolonged cardiopulmonary bypass using a large-dose regimen.

Aprotinin concentrations in the range of 127-191 kallikrein inactivator units (KIU)/mL at the end of cardiopulmonary bypass (CPB) (< 2 h duration) reduce transfusion requirements. It has been suggested that prolonged CPB may require higher infusion rates which significantly increase cost. We tested the hypothesis that large-dose aprotinin maintains therapeutic plasma levels during prolonged periods of CPB (< 2 h). Aprotinin was administered as follows: 2 x 10(6) KIU upon skin incision; 0.5 x 10(6) KIU/h x 4-h infusion on initiation of CPB; and 2 x 10(6) KIU added to the CPB prime solution. Aprotinin activity was measured 1) 30 min after initiation of drug administration (Pre-CPB); 2) 30 min after initiation of CPB (CPB + 30); 3) 90 min after initiation of CPB (CPB + 90); and 4) at CPB termination (End CPB). CPB duration (mean +/- SD) was 158 +/- 51 min. Plasma aprotinin concentrations (KIU/mL, mean +/- SD) were: 234 +/- 30 at Pre-CPB; 229 +/- 35 at CPB + 30; 184 +/- 27 at CPB + 90; and 179 +/- 22 at End CPB. In all patients, aprotinin levels at the completion of CPB were in the range previously reported to be effective. The authors conclude that large-dose regimen limited to 6 x 10(6) KIU maintained therapeutic plasma aprotinin concentrations during prolonged CPB.

The effect of heparin and its neutralisation on functional assays for factor VIIa, factor VII and TFPI.

Recently methods have become available to assay the haemostasis proteins tissue factor pathway inhibitor (TFPI) and activated factor VII (FVIIa). These assays are primarily used in research and in some studies patients may be receiving heparin therapy. We investigated the effect of heparin and its neutralisation by protamine sulphate, hexadimethrine bromide (polybrene) and triethylaminoethyl (TEAE) cellulose, on functional assays for TFPI, FVIIa and also factor VII (FVII). In the clotting assay for FVIIa using truncated recombinant tissue factor, heparin had little effect up to IU/ml, but concentrations higher than this grossly prolonged the clotting time. Protamine and polybrene neutralisation of heparin resulted in some prolongation of the clotting time despite adequate heparin neutralisation, and in addition, in the absence of heparin each of these substances themselves affected the clotting time. TEAE neutralisation of heparin appeared to be effective in the FVIIa assay, although in the absence of heparin we observed a 5% decrease in the clotting time. In the amidolytic substrate assays for TFPI and FVII, heparin with or without neutralisation resulted in only small changes in the optical density at 405nm and hence plasma levels of these factors were not significantly changed.

Haemostatic changes in the pulmonary blood during cardiopulmonary bypass.

Pulmonary injury may result from the use of cardiopulmonary bypass (CPB). We investigated changes in the haemostatic system in the pulmonary vein during CPB compared with blood that circulated through the bypass circuit. Paired samples were taken from the pulmonary vein and central venous pressure (CVP) line during the peri-operative period from ten patients. Plasma levels of factor VII (P < 0.001), prekallikrein (P < 0.05), antithrombin III (P < 0.001) and heparin cofactor II (P < 0.005) were decreased in the pulmonary vein after 20 min of bypass compared with pre-operative levels. In the pulmonary vein there was a significant increase in neutrophil expressed CD11b (P < 0.001), neutrophil elastase: alpha 1-antitrypsin complexes (P < 0.001), endothelin-1(P < 0.001) and thrombin-antithrombin complexes (P < 0.001) by the end of bypass compared with pre-operative levels. There was no significant change in monocyte expressed CD11b, factor XII or C1-esterase inhibitor in the pulmonary vein for the study period. None of these variables were significantly different in the pulmonary vein compared with CVP line. In the pulmonary vein plasma levels of activated factor VII decreased following heparin administration (P < 0.001) in the majority of patients which was coincidental to an increase (P < 0.001) in tissue factor pathway inhibitor (TFPI). This increase in TFPI was significantly higher in the pulmonary vein compared with CVP line (P < 0.05) There was a decrease in neutrophil count by 20 min on CPB in both the pulmonary vein and CVP line (P < 0.001) and this did not return to pre-operative levels in the pulmonary vein. Soluble thrombomodulin levels decreased by 20 min on CPB in the CVP line (P < 0.05) but tended to increase in the pulmonary vein, although this was not statistically significant. In conclusion we found evidence of thrombin generation and possible endothelial damage together with increased neutrophil activation and adhesion molecule expression in the pulmonary vein during CPB which may play an important role in the development of post-CPB pulmonary injury.