Plasma and cryoprecipitate manufactured from whole blood held overnight at room temperature meet quality standards

BACKGROUND: With buffy coat (BC) processing of whole blood (WB) donations, the preparation of plasma occurs within 24 hours rather than 8 hours of collection. The effect of this change on coagulation factor function in plasma and cryoprecipitate was evaluated during the validation of this production method and with routine production. STUDY DESIGN AND METHODS: Plasma frozen after an overnight hold of WB was prepared via BC or whole blood filtration (WBF) methods and quality control (QC) variables were measured. Additionally, plasma prepared with the BC method was compared to plasma produced using the platelet‐rich plasma (PRP) method with an extended plasma factor analysis. Selected plasma factor levels were also measured in both cryoprecipitate and cryosupernatant plasma prepared using the WBF method from plasma frozen on the day of collection or after an overnight hold of WB. RESULTS: When comparing BC plasma to PRP plasma, coagulation factors (F)II, VII, VIII, IX, X, and XI had somewhat lower levels, and fibrinogen and antithrombin levels were elevated. As expected the most sensitive to the prolongation of production time was FVIII with 72 and 78% of the activity of PRP plasma and cryoprecipitate, respectively. However, both still met QC standards. Similarly, products made in routine production show acceptable levels of FVIII. CONCLUSION: Plasma and cryoprecipitate products, prepared using methods in which the plasma is frozen close to 24 hours after collection, meet current quality standards. The longer WB storage time has been implemented into general use in Canada.     

Stability of coagulation factors in plasma prepared after a 24‐hour room temperature hold

BACKGROUND: The manufacture of fresh‐frozen plasma (FFP) requires that plasma be frozen within 8 hours of collection and 24‐hour frozen plasma requires 1 to 6°C refrigeration before freezing. Manufacture of plasma after a room temperature hold for 24 hours, while convenient, could compromise clotting factor levels. STUDY DESIGN AND METHODS: Pairs of FFP and 24‐hour room temperature–frozen plasma (PLT‐rich plasma [PRP]‐24HRTFP) were manufactured from PRP after a room temperature hold for 8 and 24 hours, respectively. Additional whole blood (WB) donations were kept at room temperature for 24 hours before plasma manufacture (WB‐24HRTFP). The frozen plasma products were stored at −18°C, thawed, and then stored at 1 to 6°C, with coagulation factor assays performed for up to 7 days. RESULTS: On the day of thaw, Factor (F)VIII was lower in PRP‐24HRTFP by 13% (p = 0.002) but not in WB‐24HRTFP (p = 0.3) compared to FFP. All other clotting factors were within normal range. During the postthaw period FVIII and FV declined 25 and 6%, respectively, in WB‐24HRTFP and 23 to 50% in the paired products; however, the difference between both types of 24HRTFP and FFP is insignificant by Day 7 (p > 0.05). Other clotting factors either were unchanged or showed minimal reduction (<15%). CONCLUSION: Plasma manufactured after a 24‐hour room temperature hold contains coagulation factors comparable to FFP except for a possible reduction of up to 20% in FVIII. This plasma appears suitable as a transfusable product and extension of liquid storage to 7 days merits consideration.     

Quantitative and qualitative analysis of coagulation factors in cryoprecipitate prepared from fresh‐frozen plasma inactivated with amotosalen and ultraviolet A light

BACKGROUND: There were no previous studies about the quality of cryoprecipitate prepared from fresh‐frozen plasma (FFP) inactivated with amotosalen and ultraviolet A (UVA) light. The aim of this study was to analyze the quantity and quality of coagulation factors in cryoprecipitate prepared from FFP treated with amotosalen and UVA light. STUDY DESIGN AND METHODS: FFP was obtained from whole blood donations and inactivated with amotosalen and UVA light according to the manufacturer's instructions. Fibrinogen, factor VIII (FVIII), von Willebrand factor antigen (VWF : Ag) and activity (VWF : RCo), the von Willebrand factor cleavage protease activity (ADAMTS‐13), and the multimeric structure of VWF were analyzed. RESULTS: The content of fibrinogen, FVIII, and ADAMTS‐13 was lower in cryoprecipitates prepared from amotosalen‐treated plasma when compared with cryoprecipitates prepared from nontreated plasma (35, 40, and 18% loss, respectively). The quantity and quality of VWF as well as VWF multimer patterns were not affected by the inactivation method. CONCLUSION: Cryoprecipitates prepared from amotosalen‐treated FFP contained significantly reduced levels of fibrinogen, FVIII, and ADAMTS‐13. However, the VWF quantity and quality was well preserved.     

Characterization of blood components separated from donated whole blood after an overnight holding at room temperature with the buffy coat method

BACKGROUND: With buffy coat (BC) processing of whole blood (WB) donations, increase in WB storage time to facilitate overnight holding before the separation of blood components would be a logistically attractive development. This study undertakes a comparative in vitro characterization of blood components prepared from WB samples that were either processed within 8 hours or stored overnight at room temperature before processing by the BC method. STUDY DESIGN AND METHODS: The WB units (400 mL) collected were either processed within 8 hours (fresh blood) or stored overnight (overnight blood) at room temperature. WB units were separated into individual‐component red blood cells (RBCs), BC, and plasma. The in vitro quality of these blood components (RBCs, pooled platelet concentrates [PCs], and plasma) was analyzed during storage. RESULTS: Levels of 2,3‐diphosphoglycerate (2,3‐DPG) were found to be significantly lower immediately after processing, compared with the fresh WB samples, in RBCs that had been separated from an overnight‐hold sample. However, this difference was not apparent after 14 days of storage. In pooled PCs, measurements for glucose, lactate, PO₂, PCO₂, extent of shape change, and hypotonic shock response were similar. The platelet yield in PCs prepared from an overnight‐hold WB sample was significantly higher, while CD62P expression and annexin V binding were lower (p < 0.05). For frozen plasma (FP), no significant differences were observed for the coagulation factors (F)II, FVII, FV, F IX, FX, and FXI; fibrinogen; and von Willebrand factor content between the 8‐ and 24‐hour FP. The FVIII was the component that was most sensitive to the prolongation of production time and it only had 80% of the activity of the 8‐hour FP. CONCLUSION: These data suggest that blood components (RBCs, pooled PCs, and FP) separated from WB that has been stored overnight at room temperature by the BC method are of acceptable quality.     

Evaluation and comparison of coagulation factor activity in fresh-frozen plasma and 24-hour plasma at thaw and after 120 hours of 1 to 6°C storage

BACKGROUND: Current transfusion-related acute lung injury reduction strategies include avoiding transfusion of plasma products collected from female donors or female donors that have been pregnant to reduce transfusion of plasma-containing HLA antibodies. Such a policy considerably decreases the number of donors available for generation of fresh-frozen plasma (FFP). To increase the supply of FFP, substitution of 24-hour plasma (FP24) and thawed plasma (TP) derived from either FFP or FP24 may be viable substitutes. To justify such a policy the coagulation factor content of FFP, FP24, and TP derived from both product types was assessed.
STUDY DESIGN AND METHODS: Coagulation factor (F)II, FV, FVII, FVIII, F IX, and FX; protein C (PC) and protein S (PS); von Willebrand factor antigen and ristocetin cofactor; fibrinogen; and antithrombin activities were analyzed in nonpaired FFP and FP24 at the time of product thaw and again after 120 hours of 1 to 6°C storage.
RESULTS: At thaw, mean FVIII and PC activities were lower in FP24 than FFP. Mean PC and PS activities were lower in FP24- than FFP-derived 120-hour-old TP. No other differences in mean activity reached significance. Activity levels were generally lower in TP; FVIII, FV, and FVII showed the largest changes. However, prestorage leukoreduction appears to improve the stability of FV.
CONCLUSION: FFP, FP24, and the derived TP all contain adequate coagulation factor activities to maintain hemostatic activity. As FFP becomes less available, increased use of FP24 and TP are viable alternatives for most clinical situations.     

Characterization of blood components prepared from whole-blood donations after a 24-hour hold with the platelet-rich plasma method

BACKGROUND: The preparation of platelet (PLT) concentrates (PCs) from PLT-rich plasma (PRP) requires that whole blood (WB) be processed within 8 hours of collection. Increasing WB storage time to 24 hours would be logistically attractive. This study compares the in vitro quality of blood components prepared from WB stored for 8 and 24 hours at room temperature before processing with the PRP method. STUDY DESIGN AND METHODS: WB units were collected from ABO-matched blood donors. To reduce individual variations, paired donations were drawn in parallel, pooled, and split back in the collection bag. One unit was held for 6 to 8 hours and the other for 22 to 24 hours at 20 to 24 degrees C. Prestorage leukoreduced components were prepared with the PRP as intermediate product and analyzed during storage. RESULTS: RBC units prepared after an 8- or 24-hour hold were comparable in terms of hemolysis, sodium, pH, and ATP levels. RBC 2,3- diphosphoglycerate (2,3-DPG) was significantly lower in RBCs prepared from 24-hour hold donations immediately after processing but not after 20 days of storage. Residual white blood cells were approximately fivefold higher (p < 0.05) in 24-hour RBC units. For PCs, measurements for glucose, ATP, lactate, pH, extent of shape change, hypotonic shock response, and CD62p activation were similar. No differences were observed in the von Willebrand factor, factor (F)V, FVIII, and fibrinogen content of fresh-frozen plasma. CONCLUSIONS: The decrease in FVIII and RBC 2,3-DPG can be acceptable as a compromise to improve blood component logistics, but leukoreduction efficiency must be improved before considering the adoption of an overnight storage of WB before PRP processing.     

Coagulation parameters in apheresis and leukodepleted whole-blood plasma during storage

BACKGROUND: Thawing fresh-frozen plasma (FFP) may cause delay in delivery, and one approach to circumvent this is to store plasma at +4 degrees C. Thawed plasma is commonly discarded after a few days of storage, owing to the assumption that coagulation factor activity decreases to clinically unacceptable levels. STUDY DESIGN AND METHODS: Eighteen apheresis plasma (AP) units were collected from blood donors. The collected plasma was divided into two equal parts: one part frozen at -74 degrees C as FFP and one part stored at +4 degrees C as fresh liquid plasma (FLP). Thirty-nine units of whole blood (WB) were collected from blood donors and leukodepleted by inline filtration, followed by plasma separation. Twenty plasma units were frozen at -74 degrees C as FFP and 19 plasma units were stored at +4 degrees C as FLP for 28 days. Plasma aliquots were collected before freezing and immediately after thawing FFP and before and during storage of FLP at Days 14 and 28. Factor (F)V, FVIII, D-dimers, and C1-esterase inhibitor levels were assessed. RESULTS: No significant differences in coagulation factor levels were assessed between FLP prepared from AP and FLP prepared from WB. FV and FVIII levels decreased on average 25 and 50 percent, respectively, at Day 14 of storage. C1-esterase inhibitor and D-dimers levels were not affected. CONCLUSION: Leukodepleted apheresis and WB plasma stored for 14 days retain sufficient levels of FV and FVIII activity for maintenance of normal hemostasis and could therefore be considered useful in selected clinical situations.     

The quality of fresh-frozen plasma produced from whole blood stored at 4 degrees C overnight

BACKGROUND: The aim of this study was to assess whether the quality of FFP produced from whole blood stored at 4 degrees C overnight is adequate for its intended purpose. STUDY DESIGN AND METHODS: Fresh-frozen plasma (FFP) separated from whole blood (n = 60) leukodepleted (LD) after storage at 4 degrees C overnight (18-24 hr from donation, Day 1 FFP) was compared with that LD within 8 hours of donation (Day 0 FFP, the current standard method). RESULTS: In more than 95 percent of Day 1 FFP units, levels of factor (F) II, FV, FVII, FVIII, F IX, FX, FXI, and FXII were greater than 0.50 U per mL except for von Willebrand factor (VWF) antigen and FVIII, where 92 and 87 percent of units, respectively, contained greater than 0.50 IU per mL. Compared with historical data on FFP stored for 8 hours, fibrinogen, FV, FVIII, and FXI were reduced by 12, 15, 23, and 7 percent, respectively, but other factors were not significantly reduced. Levels of VWF-cleaving protease activity were not different between FFP prepared from paired units of blood (n = 3) held for 8 or 24 hours, but were below the reference range in an additional 2 of 6 units held for 24 hours. The activities of protein S, protein C, antithrombin III, and alpha(2)-antiplasmin were reduced by less than 10 percent in Day 1 FFP (n = 20), but with final levels above the lower limit of the normal range in greater than 95 percent of units. Activated FXII antigen was not significantly raised in plasma stored for 18 to 24 hours, but levels of prothrombin fragment 1 + 2 were slightly increased (0.88 ng/mL, 18-24 hr; 0.65 ng/mL, < 8 hr). CONCLUSION: These data suggest that there is good retention of relevant coagulation factor activity in plasma produced from whole blood stored at 4 degrees C for 18 to 24 hours and that this would be an acceptable product for most patients requiring FFP.     

Coagulant stability and sterility of thawed S/D-treated plasma

BACKGROUND: Units of frozen S/D-treated plasma (SDP) must be transfused within 24 hours after thawing. To avoid waste, an attempt was made to determine how long SDP could be therapeutically effective after thawing and storing it at 20 degrees C. STUDY DESIGN AND METHODS: The microbiologic safety and the activity of labile coagulation factors were evaluated in units stored at 20 degrees C of thawed SDP units and FFP within 24 hours of collection (FFP24). Five SDP and FFP24 samples of each ABO blood group were cultured and assayed for coagulation factors daily over 5 days. Assays included FV, FVII, FVIIa, FVIII, F IX, FXI, protein S, antiplasmin, fibrinogen, prothrombin times (PTs), and activated partial thromboplastin times (aPTTs). RESULTS: None of the 80 bacterial cultures demonstrated growth under either aerobic or anaerobic conditions. FV, FVIII, F IX, FXI, fibrinogen, and the aPTT appeared to be stable in both thawed FFP24 and SDP. The PT increased slightly in thawed FFP24 and insignificantly in SDP. FVII decreased slightly in FFP24 but remained in the normal range, and FVIIa was low and constant. FVII was increased in SDP and FVIIa was markedly increased. Protein S decreased from initial normal values in FFP24 to very low values. Protein S was very low immediately after thawing in the SDP and continued to decline. Antiplasmin was normal and stable in thawed FFP24 but was low in SDP and remained constant after thawing. CONCLUSION: Sterile SDP that is stored at 20 degrees C provides sufficient coagulant activity of labile FV and FVIII to transfuse it for up to 5 days after thaw. Caution is warranted by decreases in Protein S and antiplasmin, clinical evidence of coagulopathy in some recipients of SDP, and a recent manufacturer's warning.     

Coagulation profile of liquid‐state plasma

BACKGROUND: Use of liquid plasma (LP) has been reported as early as the mid 1930s. Unlike fresh‐frozen plasma (FFP), LP is maintained at 1 to 6°C for up to 40 days after collection and processing. Despite its approved use by the US Food and Drug Administration, the coagulation profile of LP is incompletely described. In this study we evaluate the coagulation profile of LP stored up to 30 days. STUDY DESIGN AND METHODS: LP was prepared by removing plasma from nonleukoreduced whole blood within 24 hours of collection. Three LP units from each ABO group were collected and stored at 1 to 6°C. Plasma aliquots were obtained at Postcollection Days 1 to 5, 10, 15, 20, 25, and 30 and then stored at ?70°C. Each aliquot was tested for prothrombin time, activated partial thromboplastin time, and other coagulation and fibrinolytic factors. RESULTS: There was a significant decrease in Factor (F)V, FVII, FVIII, von Willebrand factor (VWF), protein S (PS) activity, and endogenous thrombin potential on Day 15 compared with Day 1. No significant difference was observed for PS antigen, D‐dimer, or thrombin‐antithrombin complex. At least 50% activity of all measured factors was noted on Day 15, compared to Day 1. Considerable heterogeneity was observed between the different blood groups for FVII, FVIII, and VWF. CONCLUSION: These data demonstrate that LP maintains at least 50% of factor activity and thrombin‐generating capacity up to 15 days of refrigerated storage. It may be more appropriate to limit LP storage and supplement with FFP when used for management of massively bleeding patients.     

Changes in coagulation factor activity and content of di(2-ethylhexyl)phthalate in frozen plasma units during refrigerated storage for up to five days after thawing

BACKGROUND: Thawed plasma is typically transfused to supply coagulation factors but factor activity declines during refrigerated storage. Refrigerating thawed plasma for longer than 24 hours could reduce plasma wastage and make plasma more readily available for emergency transfusions. We measured coagulation factor activity and di(2‐ethylhexyl)phthalate (DEHP) concentration in frozen plasma (FP) thawed and stored at 1 to 6°C for up to 5 days. STUDY DESIGN AND METHODS: FP units prepared using “top‐and‐bottom” collection sets were thawed, refrigerated, and sampled aseptically at 0, 24, 72, and 120 hours after thawing (n = 54). Clotting factor activities and prothrombin times (PTs) were measured using an automated coagulation factor analyzer. DEHP was measured by high‐performance liquid chromatography after hexane extraction (n = 11). Unit sterility was confirmed using an automated microbial detection system. RESULTS: Factor (F)V and FVIII, but not FVII, declined significantly within 24 hours. By Day 5, mean losses were 20, 14, and 41%, in FV, FVII, and FVIII, respectively; fibrinogen activity did not change. PT values were prolonged by 9% on Day 5. Mean DEHP levels increased from 22 ppm at thaw to 66 ppm on Day 5. CONCLUSIONS: The bulk of coagulation factor activity losses during storage occurred in the first 24 hours. Coagulation factor activities remaining in FP after 5 days did not differ from those previously reported in similar products frozen within 24 hours of phlebotomy. While DEHP levels in 5‐day‐thawed FP are not of concern for adult patients, for infants, DEHP levels can be minimized by using FP refrigerated for no more than 24 hours.     

普通冰冻血浆与新鲜冰冻血浆部分血浆组分的比较

目的:比较普通冰冻血浆(FP)和新鲜冰冻血浆(FFP)中血浆组分的差异。方法:随机选择北京市红十字血液中心提供的FP和FFP各20份,血浆融化后即刻分别检测凝血因子、纤溶系统及抗凝蛋白指标等12种血浆组分,即活化的部分凝血活酶时间(APTT)、凝血酶原时间(PT)、凝血因子Ⅷ(FⅧ)活性、凝血因子Ⅴ(FⅤ)活性、纤维蛋白原(FIB)水平、血管性血友病因子裂解蛋白酶(ADAMTS-13)活性、血管性血友病因子(v WF)活性、D-二聚体(D-dimer,DD)、纤维蛋白降解产物(fibrin degradation products,FDP)、抗凝血酶(antithrombin,AT)、蛋白C(protein C,PC)、蛋白S(protein S,PS),并进行比较分析。结果:与FFP相比,FP中APTT明显延长(t=3.428,P<0.01),PT延长(z=-2.140,P<0.05),FⅧ活性明显降低(t=-3.372,P<0.01),但均在参考区间内;PS活性降低(t=-2.458,P<0.05);两种血浆中其余组分的差异无统计学意义(P>0.05)。结论:与FFP相比,FP缺乏某些凝血因子和抗凝蛋白,但可替代FFP应用于部分疾病的治疗。     

Coagulation factor levels in plasma frozen within 24 hours of phlebotomy over 5 days of storage at 1 to 6 degrees C

BACKGROUND: The use of plasma frozen within 24 hours after phlebotomy (FP24) is likely to increase as male donors become the predominant source of plasma products. This study was performed to investigate the levels of clotting factors in thawed plasma (TP) prepared from FP24 during 5 days of storage at 1 to 6°C. STUDY DESIGN AND METHODS: Five units of A, B, and O and 3 units of AB FP24 were obtained from the local blood provider. They were thawed and maintained at 1 to 6°C for a total of 5 days. Within 6 hours of thawing and every 24 hours thereafter for 5 days, each unit was assayed for the following clotting factors: Factor (F)II, FV, FVII, FVIII, F IX, FXI, FXII, antithrombin (AT), protein C (PC), and protein S (PS). ADAMTS‐13 was assayed on Days 2, 4, and 5. Time is expressed as mean hours or days (standard deviation). RESULTS: On average the units were frozen 21.3 (3.8) hours after phlebotomy and had been frozen for a mean of 30.1 (32.3) days before thawing. The activities of all procoagulant factors including FVIII, along with AT, PC, and ADAMTS‐13, were well maintained in their normal range during the 5‐day storage. The activity of PS was slightly below the normal range by Day 5. CONCLUSIONS: The activity of all factors assayed, except for PS, were within their normal range during the 5‐day storage period. These results show comparable factor assay levels in TP prepared from fresh‐frozen plasma and FP24.     

Comparison of coagulation factor XIII content and concentration in cryoprecipitate and fresh-frozen plasma

BACKGROUND: For patients with plasma coagulation factor XIII (pFXIII) deficiency, recommended means of replacement include infusions of fresh‐frozen plasma (FFP), cryoprecipitate, or (where available) factor (F)XIII concentrates. Quantitative differences in pFXIII concentration in FFP and cryoprecipitate are not well defined and were, therefore, the subject of this study. STUDY DESIGN AND METHODS: FFP and cryoprecipitate (10 bags each from blood group O donors) were analyzed to quantify pFXIII activity and antigen. Coagulation FVIII, fibrinogen, and von Willebrand factor (VWF) were also quantitated. RESULTS: Mean (±SD) pFXIII activity in cryoprecipitate and FFP bags was 60 ± 30 and 288 ± 77 U per bag, respectively, and pFXIII antigen and activity levels were concordant. Other comparisons (mean ± SD) between cryoprecipitate and FFP, respectively, were as follows: coagulation FVIII activity, 133 ± 37 and 265 ± 83 U per bag; fibrinogen content (Clauss kinetic assay), 183 ± 44 and 725 ± 199 mg per bag; VWF antigen content, 181 ± 53 and 218 ± 70 U per bag; VWF ristocetin cofactor activity, 168 ± 34 and 221 ± 65 U per bag; VWF collagen‐binding activity, 164 ± 40 and 208 ± 71 U per bag; and fluid (plasma) volumes per bag, 21.3 ± 2.7 and 245 ± 29 mL. CONCLUSION: In contrast to other cryoprecipitable coagulation proteins, pFXIII is only mildly enriched in cryoprecipitate when compared with FFP (approx. two‐ to threefold). Although both products can provide effective pFXIII replacement, FFP may be preferred when infusion volume is not a major consideration and pFXIII concentrates are not available. VWF is substantially enriched in cryoprecipitate (approx. ninefold compared with its concentration in FFP), with VWF activity content exceeding that of FVIII by approximately 26 percent on average.     

Evaluation of in vitro storage properties of prestorage pooled whole blood–derived platelets suspended in 100 percent plasma and treated with amotosalen and long-wavelength ultraviolet light

BACKGROUND: Amotosalen, a psoralen, has been utilized for photochemical treatment (PCT) of apheresis platelets (PLTs) and pooled buffy coat PLTs suspended in additive solution. In the United States, the source of many PLT transfusions is from whole blood–derived PLTs prepared by the PLT‐rich plasma (PRP) method. This study investigated the in vitro PLT properties of amotosalen‐PCT of leukoreduced pools of PLTs prepared by the PRP method and suspended in 100 percent plasma. STUDY DESIGN AND METHODS: On Day 1 of storage, 12 leukoreduced (n = 6) or 10 leukoreplete (n = 6) ABO‐identical PLT concentrates were pooled, separated into two pools of 6 or 5 units, respectively, and leukoreduced (leukoreplete pools only). Each pool of 5 or 6 units was then photochemically treated (designated “test”: amotosalen plus 3.0 J/cm² long‐wavelength ultraviolet light followed by amotosalen/photoproduct removal) while the remaining identical pool (designated “control”) was untreated. PLT in vitro assays were performed on test and control pools during 7‐day storage. RESULTS: PCT resulted in slightly reduced pH in test pools compared to that of matched control pools after 5 days of storage (5‐unit pools: test, 6.96 ± 0.12 vs. control, 7.15 ± 0.09, p = 0.0033; 6‐unit pools: test, 6.90 ± 0.10 vs. control, 7.07 ± 0.09, p < 0.0001). Test pools adequately maintained many other in vitro properties including PLT morphology, hypotonic shock response, and extent of shape change parameters during 5‐day storage, which, like pH, also differed from those of controls. The pH of test and control pools declined on Day 7, with 1 of 6 test pools (either 5 or 6 units) having a pH value of less than 6.20, while all control pools had pH values of more than 6.66. CONCLUSION: PCT of leukoreduced PLT pools of whole blood–derived PLTs in 100 percent plasma maintained adequate PLT in vitro variables through 5 days of storage.     

Stability of solvent/detergent-treated plasma and single-donor fresh-frozen plasma during 48 h after thawing.

The aim of this study was to compare the quality of solvent/detergent (SD) treated plasma, Octaplas, and single-donor fresh-frozen plasma (FFP) units during 48-h storage after thawing. Octaplas bags of different blood groups and individual FFP units were thawed and stored at either +4 degrees C or at room temperature (RT) for 48 h. Samples drawn during the observation period were investigated on various coagulation factor and protease inhibitor activities using standard coagulation and chromogenic assays. The generation of FVIIa was followed as a marker of coagulation factor activation. All investigated coagulation factors and protease inhibitors were stable for at least 8h during storage of Octaplas at +4 degrees C. FVIII levels started to decline earlier in FFP than in Octaplas at both storage temperatures. Stored Octaplas OD660 values were more stable during the storage period than FFP OD660 values, whereas VWF multimeric patterns were comparably stable in both types of plasma. In conclusion, this stability study has demonstrated that thawed Octaplas maintains its high quality, even with a time safety margin, for 8 h at +4 degrees C and for 6 h at RT. In general, there was more variability in coagulation factor levels among different FFP units compared with different Octaplas batches.     

Plasma transfusion in liver transplantation: a randomized,double‐blind,multicenter clinical comparison of three virally secured plasmas

BACKGROUND: The clinical equivalence of plasma treated to reduce pathogen transmission and untreated plasma has not been extensively studied. A clinical trial was conducted in liver transplant recipients to compare the efficacy of three plasmas. STUDY DESIGN AND METHODS: A randomized, equivalence, blinded trial was performed in four French liver transplantation centers. The three studied (fresh‐frozen) plasmas were quarantine (Q‐FFP), methylene blue (MB‐FFP), and solvent/detergent (S/D‐FFP) plasmas. The primary outcome was the volume of plasma transfused during transplantation. Secondary outcomes included intraoperative blood loss, hemostasis variables corrections, and adverse events. RESULTS: One‐hundred patients were randomly assigned in the MB‐FFP, 96 in the S/D‐FFP, and 97 in the Q‐FFP groups, respectively. The median volumes of plasma transfused were 2254, 1905, and 1798 mL with MB‐FFP, S/D‐FFP, and Q‐FFP, respectively. The three plasmas were not equivalent. MB‐FFP was not equivalent to the two other plasmas, but S/D‐FFP and Q‐FFP were equivalent. The median numbers of transfused plasma units were 10, 10, and 8 units with MB‐FFP, S/D‐FFP, and Q‐FFP, respectively. Adjustment on bleeding risk factors diminished the difference between groups: the excess plasma volume transfused with MB‐FFP compared to Q‐FFP was reduced from 24% to 14%. Blood loss and coagulation factors corrections were not significantly different between the three arms. CONCLUSION: Compared to both Q‐FFP and S/D‐FFP, use of MB‐FFP was associated with a moderate increase in volume transfused, partly explained by a difference in unit volume and bleeding risk factors. Q‐FFP was associated with fewer units transfused than either S/D‐FFP or MB‐FFP.     

Analysis of prolonged storage on coagulation Factor (F)V,FVII, and FVIII in thawed plasma: is it time to extend the expiration date beyond 5 days?

BACKGROUND: According to AABB standards, fresh‐frozen plasma (FFP) should be thawed at 30 to 37°C and expire after 24 hours. An increase in the aggressive management of trauma patients with thawed plasma has heightened the risk of plasma waste. One way to reduce plasma waste is to extend its shelf life, given that the full range of therapeutic efficacy is maintained. We evaluated the effect of prolonged storage at 1 to 6°C on the activity of Factor (F)V, FVII, and FVIII in plasma thawed at 37 or 45°C. STUDY DESIGN AND METHODS: Group O plasma from healthy donors (n = 20) was divided into 10 pairs and frozen and stored at not more than ?18°C. One sample from each pair was thawed at 37 or 45°C, and all were stored at 1 to 6°C. Samples were analyzed for FV, FVII, and FVIII activity on Days 0, 5, 10, 15, and 20. RESULTS: Plasma thawing time was 17% less at 45°C than at 37°C. No differences were observed between thawing groups in coagulation activity of FV, FVII, and FVIII during the 20‐day storage period (p > 0.12). In both groups, the activity of FV and FVIII decreased over time but remained within a normal range at 10 days. CONCLUSION: Although levels of plasma clotting factors are reduced in storage, therapeutic levels of FV and FVIII are maintained in thawed plasma stored for up to 10 days at 1 to 6°C. Thawing of FFP at 45°C decreases thawing time but does not affect the activity of FV, FVII, and FVIII.     

The use of fresh‐frozen plasma in England: high levels of inappropriate use in adults and children

BACKGROUND: Fresh‐frozen plasma (FFP) is given to patients across a range of clinical settings, frequently in association with abnormalities of standard coagulation tests. STUDY DESIGN AND METHODS: A UK‐wide study of FFP transfusion practice was undertaken to characterize the current patterns of administration and to evaluate the contribution of pretransfusion coagulation tests. RESULTS: A total of 4969 FFP transfusions given to patients in 190 hospitals were analyzed, of which 93.3% were in adults and 6.7% in children or infants. FFP transfusions to adults were given most frequently in intensive‐treatment or high‐dependency units (32%), in operating rooms or recovery (23%), or on medical wards (22%). In adult patients 43% of all FFP transfusions were given in the absence of documented bleeding, as prophylaxis for abnormal coagulation tests or before procedures or surgery. There was wide variation in international normalized ratio (INR) or prothrombin times before FFP administration; in 30.9% of patients where the main reason for transfusion was prophylactic in the absence of bleeding the INR was 1.5 or less. Changes in standard coagulation results after FFP administration were generally very small for adults and children. CONCLUSIONS: This study raises important questions about the clinical benefit of much of current FFP usage. It highlights the pressing need for better studies to inform and evaluate quantitative data for the effect of plasma on standard coagulation tests.     

Refreezing previously thawed fresh-frozen plasma. Stability of coagulation factors V and VIII:C

With the growth in autologous blood programs and the increased scrutiny of the indications for transfusion of fresh-frozen plasma (FFP), an increase has been seen in the number of occasions on which FFP was requested and thawed but then not transfused. The coagulation properties of FFP units that were refrozen and then rethawed were therefore studied. Fifty-eight units of plasma were studied, with each experimental unit of FFP paired with an identical control unit. Experimental units were frozen, stored at -65 degrees C, thawed, stored at 1 to 6 degrees C for various periods of time up to 24 hours, and then refrozen, stored at -65 degrees C, rethawed, and stored again in the refrigerator for up to 24 hours. Control units were frozen once at the time the experimental units were first frozen and thawed once at the time of the second thaw of the experimental units. Aliquots of plasma were sampled periodically and were later batch-tested for prothrombin time (PT), activated partial thromboplastin time (aPTT), and factor V and VIII:C activity. The results of coagulation testing of the twice-frozen plasmas were always within the normal range. There was a slight but statistically valid prolongation of the PT and aPTT and a decrease in the factor V and VIII:C levels for twice-frozen plasma compared with control plasma. The greatest decline occurred in the level of factor VIII:C. The measured deterioration in coagulation of twice-frozen FFP is unlikely to be of clinical importance. Refreezing FFP may eventually prove useful for rare donor, autologous, and massive transfusion programs.