Introduction of EUBIS standards to upgrade inspections of blood establishments to improve the safety of blood transfusion: The Polish experience.

BACKGROUND AND OBJECTIVES: The competent authority (CA) responsible for external inspections of Polish blood establishments (BEs) and supervision of the quality system is the Institute of Haematology and Transfusion Medicine (IHTM). Before the implementation of the European Blood Inspection System (EuBIS) classification of non-compliance, the IHTM inspections were conducted according to national guidelines and the non-compliance-related recommendations were based on the inspectors' own experience and interpretation of the observed problems. Since 2009, IHTM inspections were already performed according to EuBIS guidelines. The study assessed the impact of the EuBIS classification on the IHTM recommendations. We assumed that the implementation of consistent assessment criteria contributed to the upgrading of the quality of BE inspections. MATERIALS AND METHODS: BE-inspection protocols; 30 from 2009 to 2010 and 61 from 2016 to 2019. Non-compliance-related recommendations were classified according to the seriousness of non-compliances (critical, major, other significant, and observation) and also to the area of BE activity (documentation, organisation of work, qualification and validation, pathway from donor qualification to blood component-issue, quality control of blood components, adverse events and reactions). RESULTS: The recommendations mostly referred to document-keeping and work organisation and were distributed as follows: 2009-2 critical (others unclassified), 2010-1-13 major, 4-25 other significant and 1-7 suggestions, 2016-2019-3-9 critical, 90-196 major, and 157-297 other significant as well as 14-22 suggestions. CONCLUSION: Polish BEs still require: integrated document management, analysis of IHTM recommendations, implementation of corrective and preventive measures and personnel training in identifying similar non-compliances in other procedures.

Human Intramuscular Hyperimmune Gamma Globulin (hIHGG) Anti-SARS-CoV-2-Characteristics of Intermediates and Final Product.

This study aims to characterize the intermediates, and the final product (FP) obtained during the production of human intramuscular hyperimmune gamma globulin anti-SARS-CoV-2 (hIHGG anti-SARS-CoV-2) and to determine its stability. Material and methods: hIHGG anti-SARS-CoV-2 was fractionated from 270 convalescent plasma donations with the Cohn method. Prior to fractionation, the plasma was inactivated (Theraflex MB Plasma). Samples were defined using enzyme immunoassays (EIA) for anti-S1, anti-RBD S1, and anti-N antibodies, and neutralization assays with SARS-CoV-2 (VN) and pseudoviruses (PVN, decorated with SARS-CoV-2 S protein). Results were expressed as a titer (EIA) or 50% of the neutralization titer (IC50) estimated in a four-parameter nonlinear regression model. Results: Concentration of anti-S1 antibodies in plasma was similar before and after inactivation. Following fractionation, the anti-S1, anti-RBD, and anti-N (total tests) titers in FP were concentrated approximately 15-fold from 1:4 to 1:63 (1800 BAU/mL), 7-fold from 1:111 to 1:802 and from 1:13 to 1:88, respectively. During production, the IgA (anti-S1) antibody titer was reduced to an undetectable level and the IgM (anti-RBD) titer from 1:115 to 1:24. The neutralizing antibodies (nAb) titer increased in both VN (from 1:40 to 1:160) and PVN (IC50 from 63 to 313). The concentration of specific IgG in the FP did not change significantly for 14 months. Conclusions: The hIHGG anti-SARS-CoV-2 was stable, with concentration up to approximately 15-fold nAb compared to the source plasma pool.

Assessing quality of blood components derived from whole blood treated with riboflavin and ultraviolet light and separated with a fully automated device.

BACKGROUND: Combining pathogen reduction and automated separation of whole blood (WB), together with the use of improved additive solutions, may increase reproducibility and extend shelf-life of blood components. MATERIALS AND METHODS: Forty WB units were collected from volunteer donors and randomised 1:1 into two groups: 1) pathogen reduction with riboflavin and ultraviolet light (PRT); or 2) no treatment (Control). After two hours (h) at room temperature, all units underwent fully automated separation into red blood cell concentrate (RBCC), plasma and leukopack components. RBCCs were leukoreduced and stored in phosphate-adenine-glucose-guanosine-saline-mannitol (PAGGSM) solution while plasma units were shock frozen within 8 h of collection and stored at ≤ -25°C. RBCCs were sampled on day 1 and weekly thereafter until day 42, while plasma was sampled on days 1 and 30. The main study objective was to assess the in vitro quality of separated RBCCs using biochemical and haematological parameters. Plasma protein content after one cycle of freeze-thaw was also analysed. RESULTS: The quality of RBCCs was largely comparable between the PRT and Control groups, except for a significantly higher degree of haemolysis and extracellular potassium levels in the PRT group after 35 days of storage. While potassium concentration was significantly higher in the PRT group at all timepoints, the degree of haemolysis exceeded the accepted European threshold (i.e., <0.8% of red cell mass in ≥ 90.0% of tested units) after day 35. Most plasma protein levels were significantly lower in the PRT than the Control group at both day 1 and day 30. DISCUSSION: Pathogen reduction with riboflavin and ultraviolet light treatment of WB can be combined with fully automated separation to obtain RBCCs that may be stored for up to 35 days in PAGGSM solution with acceptable quality, comparable to that of RBCCs from untreated blood. The relative differences between factor concentrations in plasma from the PRT and the Control groups were similar during the 30-day storage.

Plasma pooling in combination with amotosalen/UVA pathogen inactivation to increase standardisation and safety of therapeutic plasma units.

OBJECTIVES: Assessment of the impact of pooling five single-donor plasma (SDP) units to obtain six pathogen-reduced therapeutic plasma (PTP) units on standardisation and the retention of labile coagulation factors. BACKGROUND: SDP shows a high inter-donor variability with potential implications for the clinical treatment outcome. Additionally, there is still an existing risk for window-period transmissions of blood borne pathogens including newly emerging pathogens. METHODS/MATERIALS: Five ABO-identical SDP units were pooled, treated with the INTERTCEPT™ Blood System (Cerus Corporation, U.S.A.) and split into six PTP units which were frozen and thawed after 30 days. The variability in volume, labile coagulation factor retention and activity was assessed. RESULTS: The variability of volumes between the PTP units was reduced by 46% compared to SDP units. The variability in coagulation factor content between the PTP units was reduced by 63% compared to SDP units. Moderate, but significant losses of coagulation factors (except for vWF) were observed in PTPs compared to SDPs. CONCLUSION: The pooling of five SDP units to obtain six PTP units significantly increases product standardisation with potential implications for safety, economics as well as transfusion-transmitted pathogen safety, making it an interesting alternative to quarantine SDP (qSDP) and pathogen-reduced SDP.

Identification and follow-up of pregnant women with platelet-type human platelet antigen (HPA)-1bb alloimmunized with fetal HPA-1a.

INTRODUCTION: Pregnant women negative for human platelet antigen 1a (HPA-1a) are at risk of alloimmunization with fetal HPA-1a antigen inherited from the father, and their offspring may develop fetal and neonatal alloimmune thrombocytopenia (FNAIT). The aim of this study was to analyze the frequency of HPA-1a alloimmunization in pregnant Polish women, the feasibility of using maternal platelets for intrauterine transfusions in women subjected to diagnostic fetal blood sampling (FBS) and to discuss potential consequences of alloimmunization. MATERIAL AND METHODS: Fifteen thousand two hundred and four pregnant women were typed for HPA-1a; HPA-1a negative were screened for anti-HPA-1a. Alloimmunized women received specialist perinatology care; some of them were subjected to FBS, followed by transfusion of HPA-1a negative platelet concentrates (PC) prepared from maternal blood. RESULTS: Three hundred seventy-three (2.5%) women were HPA-1a negative, and 32 (8.6%) tested positively for anti-HPA-1a. Antibodies were detected in 22 women during pregnancy. Diagnostic FBS followed by PC transfusion was performed in 14 woman, who were platelet donors for their 16 unborn babies. Blood donations were tolerated well by the patients, and also intrauterine platelet transfusions were uneventful. Pharmacotherapy with intravenous immunoglobulins was implemented in 11/22 patients. CONCLUSIONS: HPA-1a negative women (ca. 2.5% of all pregnant patients) are at risk of alloimmunization with HPA-1a antigen and developing FNAIT. Alloimmunized women can be donors of platelets for their offspring providing removal of antibodies from PC. Owing to potential complications, special care should be taken if an alloimmunized woman was qualified as a blood or stem cell recipient.

Quality control of riboflavin-treated platelet concentrates using Mirasol® PRT system: Polish experience.

BACKGROUND: The quality of platelet concentrates (PCs) is affected by preparation, storage, the type of container, and pathogen reduction technology (PRT). The Mirasol® Pathogen Reduction Technology (PRT) system (Terumo BCT Inc., Lakewood, USA), which uses riboflavin and ultraviolet (UV) light, has recently been proven effective against bacteria, viruses, parasites, and leukocytes. OBJECTIVES: The aim of the study was to evaluate the effect of the Mirasol® PRT system, based on riboflavin and UV light exposure, on the most common in vitro platelet quality parameters of PCs prepared from whole blood-derived buffy coats. MATERIAL AND METHODS: The study included 15 trials (n = 15). For each trial, 2 PCs were used: 1 for treatment with the Mirasol® PRT system (M) and 1 for a control (C). In the M group, PCs were illuminated. In the C group, saline solution was added. PCs from groups M and C were stored at 20-24°C, with agitation. Samples were collected on days 1, 3 and 5 to determine platelet concentration, total platelet count/unit, mean platelet volume (MPV), power of hydrogen (pH), glucose and beta-thromboglobulin concentration (BTG), hypotonic shock response (HSR), aggregation, CD42b and CD62P expression, pCO2, and pO2. RESULTS: No significant differences in HSR or CD42b expression were observed between groups M and C. All pH values were stable during the whole storage period (7.1-7.5). On storage day 1, CD62P expression in group C was significantly higher than in group M. In the Mirasol® group, significantly higher glucose consumption was noted on storage days 3 and 5. On day 5, a 2-3-fold increase in BTG was observed in both groups as compared to day 1; on day 5, BTG concentration was 32% higher in group M than in group C. On all storage days, pCO2 was comparable in groups M and C; lower pO2 values were reported for group M. CONCLUSIONS: In vitro results demonstrated that pH, HSR, aggregation, CD42b antigen expression, and MPV and platelet count parameters were comparable in groups M and C.

Study of CD69 antigen expression and integrity of leukocyte cellular membrane in stored platelet concentrates following irradiation and treatment with Mirasol® PRT System.

BACKGROUND: Leukocytes in transfused blood components, particularly residual lymphocytes, have been shown to contribute to the occurrence of various adverse reactions. One of the most severe is transfusionassociated graft versus host disease (TA-GvHD) following transfusion of blood components contaminated with immunocompetent T lymphocytes. Irradiation is a routine method for protection against TA-GvHD. According to the literature, some pathogen reduction methods have also been proven effective for the inactivation of T lymphocytes, and so they may be considered as an alternative to irradiation. OBJECTIVES: Comparison of CD69 antigen expression and the integrity of the leukocyte cellular membrane in stored platelet concentrates (PCs) following irradiation with the Gammacell 3000 Elan (Nordion Inc., Ottawa, Canada) and treatment with the Mirasol® Pathogen Reduction Technology (PRT) System (Terumo BCT, Lakewood, USA). MATERIAL AND METHODS: The study included seven experiments. For each experiment we used 3 PCs, for Mirasol® PRT System treatment (M), for Gammacell 3000 Elan irradiation (R), and for the control (C). 7-amino-actinomycin D (7-AAD, Becton Dickinson, Franklin Lakes, USA) permeability was used to determine lymphocyte viability while CD69 antigen expression was the marker of lymphocyte activation. Analyses of 7-AAD and CD69 antigen expression were performed in a FACS Canto I flow cytometer (Becton Dickinson, USA). RESULTS: During 6 storage days, viable lymphocyte count decreased to 28% (p = 0.001) in the Mirasol® PRT System treated PCs and to 65% (p = 0.004) in the irradiated PCs. A statistically significant increase in CD69 expression in the irradiated PCs was observed; 1.3-fold on day 3 and 1.5-fold on day 6. In the Mirasol ® PRT System treated PCs, no statistically significant increase was observed. CONCLUSIONS: The in vitro results suggest that the Mirasol® PRT System is as effective as irradiation due to donor leukocyte inactivation capacity.

Hemovigilance survey of pathogen-reduced blood components in the Warsaw Region in the 2009 to 2013 period.

BACKGROUND: In 2009 the Mirasol Pathogen Reduction Technology (PRT) was introduced to the routine blood component production of the Regional Blood Transfusion Center in Warsaw (RBTCW). The goal of this study was to investigate the safety of Mirasol-treated blood components. STUDY DESIGN AND METHODS: The accumulated passive hemovigilance data of Mirasol-treated blood components collected at the RBTCW are presented and compared to historical and contemporary data. Furthermore, active hemovigilance data collected from patients with different hematologic disorders transfused with Mirasol-treated or untreated blood components at the Institute of Hematology and Transfusion Medicine (IHTM) are presented and discussed. RESULTS: The adverse reaction (AR) reporting rate by hospitals to the RBTCW after the implementation of the Mirasol technology was 0.39% for Mirasol-treated platelet concentrates (M-PCs) and 0.05% for Mirasol-treated fresh-frozen plasma. When comparing contemporary rates of ARs recorded by RBTCW in the time period 2011 to 2012, no statistical difference was observed between Mirasol-treated and untreated blood components. No serious AR was attributed to Mirasol-treated components. At the IHTM a lower rate of ARs after transfusion of M-PCs was observed than with untreated PCs. Despite the fact that very large amounts of Mirasol-treated plasma have been transfused to patients with congenital or acquired thrombotic thrombocytopenic purpura, no significant increase in AR rates was observed. CONCLUSION: Treatment of blood components with the Mirasol PRT System has proven to be safe for patients and is not associated with increased rates and grades of adverse events in patients of hospitals in the Warsaw Region.

Introducing Pathogen Reduction Technology in Poland: A Cost-Utility Analysis.

BACKGROUND: Mirasol® pathogen reduction technology (PRT) uses UV light and riboflavin to chemically inactivate pathogens and white blood cells in blood components. In the EU, Mirasol PRT is CE-marked for both plasma and platelet treatment. In Poland, the decision to introduce PRT treatment of the national supply of fresh frozen plasma has spurred interest in evaluating the cost-effectiveness of this strategy. METHODS: A decision-analytic model evaluated the incremental costs and benefits of introducing PRT to the existing blood safety protocols in Poland. RESULTS: Addition of PRT treatment of plasma to current screening in Poland is estimated to cost 2.595 million PLN per quality-adjusted life year (QALY) (610,000 EUR/QALY); treating both plasma and platelet components in addition to current safety interventions had a lower cost of 1.480 million PLN/QALY (348,000 EUR/QALY). CONCLUSIONS: The results suggest that in Poland the cost per QALY of PRT is high albeit lower than found in previous economic analyses of PRT and nucleic acid testing in North America. Treating both platelets and plasma components is more cost-effective than treating plasma alone. Wide confidence intervals indicate high uncertainty; to improve the precision of the health economic evaluation of PRT, additional hemovigilance data are needed.

Methods of freezing cord blood hematopoietic stem cells.

BACKGROUND: Cord blood (CB) is a valuable source of hematopoietic stem cells (HSCs). Extended storage of CB is possible provided that validated cryopreservation procedures are used. The study objective was to determine optimal methods of CB cryopreservation. STUDY DESIGN AND METHODS: In the study we 1) compared the effect of two-step cryopreservation and controlled-rate freezing method on the postthaw quality of CB (Study A) and 2) evaluated the postthaw quality of HSC fractions isolated from CB with various methods and frozen with controlled-rate freezing method (Study B). The same cryoprotectant mixture was used for 20 CB units (Study A) and 122 CB units (Study B). RESULTS: In Study A, 13.79 × 10(8) and 13.29 × 10(8) initial white blood cell (WBC) counts decreased to 6.38 × 10(8) and 6.02 × 10(8) after thaw for the two methods, respectively. The mononuclear cell (MNC) counts decreased from 5.90 × 10(8) to 3.71 × 10(8) and from 5.64 × 10(8) to 3.47 × 10(8) dependent on the method. MNC viability decreased from 99.0% to 97.4% for the former and from 98.5% to 97.2% for the latter method. The differences were insignificant. In Study B, postthaw WBC recovery in HSC fractions was 74.4% to 103.5%, MNC recovery 106.4% to 118.5%, CD34+ cell recovery 102.5% to 150.2%, and MNC viability 94.1% to 97.4%. CONCLUSION: Neither the cryopreservation procedure nor the freezing of isolated HSCs affected product quality, which may indicate that various freezing methods can be used for cell banking provided the they follow recommendations of good manufacturing practice and Directive 2004/33/EC.

Lysophosphatidylcholines: bioactive lipids generated during storage of blood components.

Transfusion-related acute lung injury (TRALI) is suggested to be a "two hit" event, resulting from priming and activation of pulmonary neutrophils. It is known that neutrophil activation may result from infusion of lysophosphatidylcholines (LysoPCs) accumulated during storage of blood components. The aim of our study was to verify whether the LysoPCs are released into the storage medium of blood components. We measured the LysoPCs concentration in the supernatants from stored apheresis platelet concentrates (PLTs), packed non-leukoreduced red blood cell concentrates (RBCs), leukoreduced red blood cell concentrates (L-RBCs), fresh frozen plasma (FFP) and donor plasma (control). Lipids were separated on high-performance thin-layer chromatography, detected by primulin spray and quantified by photodensitometric scanning. The LysoPCs concentration in donor plasma was similar to that in FFP. During storage the LysoPCs content in PLTs increased almost two-fold as compared to the fresh isolated platelets. In RBCs and L-RBCs the LysoPC level was very low or below detection limit and did not increase throughout the storage period. According to our observations bioactive LysoPCs may be considered a neutrophil-activating factor only following PLT transfusions but not RBCs transfusions.