Perbedaan PERBEDAAN NILAI LEKOSIT ANTARA KOMPONEN DARAH PACKED RED CELLS (PRC) DAN PACKED RED CELLS LEUCODEPLETED (PRC-LD) DI UTD PMI KOTA SURABAYA TAHUN 2019

This leukodepleted PRC (PRC-LD) is considered capable of preventing reactions related to blood transfusions because it contains only a small number of leukocytes. The blood component of PRC-LD has also been shown to prevent or reduce transfusion reactions. Leukodepleted is a procedure to reduce the number of leukocytes in the blood or blood components to be transfused to a minimum of <1x106 leukocytes/unit (European standard) or reduce the number of leukocytes >99%. The purpose of this study was to see the difference in leukocyte values ​​in the PRC and PRC-LD components. The method used is analytic, namely research that aims to determine the relationship between variables within the scope of the laboratory. The method used is a comparative study. This study used 30 samples of PRC products and 30 samples of Leucodepleted PRC products at UTD PMI Surabaya City with 450 cc bags. The study was conducted in October - December 2019. The result was that the leukocyte value in the PRC blood component contained blood quality that did not meet the specifications as many as 30 bags (100%) had leukocyte levels >1x106 per bag. Meanwhile, the blood component of PRC-LD contains blood quality that meets the specifications as many as 30 bags (100%), having leukocyte levels <1x106 per bag. Conclusion The quality of PRC Leukodepleted blood component products, the quality of leukocyte levels that meet the specifications, there are 30 blood bags (100%). Keywords: Packed Red Cells Leukodepleted

Platelet Toll-Like Receptor 4–Related Innate Immunity Potentially Participates in Transfusion Reactions Independent of ABO Compatibility: An Ex Vivo Study

The role of platelet TLR4 in transfusion reactions remains unclear. This study analyzed platelet TLR4 and certain damage-associated molecular patterns (DAMPs) and evaluated how ABO compatibility affected TLR4 expression after a simulated ex vivo transfusion. A blood bank was the source of donor red blood cells. Blood from patients undergoing cardiac surgery was processed to generate a washed platelet suspension to which the donor blood was added in concentrations 1, 5, and 10% (v/v). Blood-mixing experiments were performed on four groups: a 0.9% saline control group (n = 31); a matched-blood-type mixing group (group M, n = 20); an uncross-matched ABO-specific mixing group (group S, n = 20); and an ABO-incompatible blood mixing group (group I, n = 20). TLR4 expression in the platelets was determined after blood mixing. We evaluated levels of TLR4-binding DAMPs (HMGB1, S100A8, S100A9, and SAA), lipopolysaccharide-binding protein, and endpoint proteins in the TLR4 signaling pathway. In the M, S, and I groups, 1, 5, and 10% blood mixtures significantly increased TLR4 expression (all p < 0.001) in a concentration-dependent manner. Groups M, S, and I were not discovered to have significantly differing TLR4 expression (p = 0.148). HMGB1, S100A8, and S100A9 levels were elevated in response to blood mixing, but SAA, lipopolysaccharide-binding protein, TNF-α, IL-1β, and IL-6 levels were not. Blood mixing may elicit innate immune responses by upregulating platelet TLR4 and DAMPs unassociated with ABO compatibility, suggesting that innate immunity through TLR4-mediated signaling may induce transfusion reactions.

Management of hemolytic transfusion reactions

Delayed hemolytic transfusion reactions (DHTRs) in patients with sickle cell disease are underappreciated and potentially fatal. Patients with DHTRs typically have symptoms of pain or dark urine days to weeks following a red blood cell (RBC) transfusion. In instances of DHTRs with hyperhemolysis, the patient's hemoglobin (Hgb) may be significantly lower than it was pretransfusion, and the Hgb A may drop by more than 50%. In most cases, at least 1 RBC alloantibody and sometimes multiple RBC alloantibodies can be identified during the DHTR, with those antibodies presumably having fallen below the level of detection at the time of the implicated transfusion. However, in up to one-third of cases, no new RBC alloantibodies can be identified posttransfusion. Complement is increasingly being appreciated to play a role in DHTRs and hyperhemolysis, not only due to classic pathway activation (with complement fixed antibody bound to RBCs) but also due to alternative pathway activation (resulting in part from plasma free heme). As such, anti-C5 inhibition has recently been reported to be effective at mitigating hemolysis in the setting of some severe DHTRs. Transfusion avoidance during DHTRs is recommended if possible, with long-term transfusion support advice being less clear; for example, a history of a severe DHTR may lead to questions regarding the safety of transfusions prior to curative therapies such as stem cell transplantation or gene therapy. A better understanding of antibody-positive and antibody-negative DHTRs, including patient- or disease-specific risk factors, is necessary to improve transfusion safety.

Pattern of Blood Transfusion Reactions in Sokoto Specialist Hospital, Sokoto, Nigeria

No Abstract.

Frequency and Nature of Transfusion Related Adverse Reactions in Patients Admitted in A Tertiary Care Hospital

Background:Transfusion of blood and blood products if employed safely, with intensive care can save manyvaluable lives. But a number of transfusion reactions may develop that are sometimesmore serious and life threatening.So this study was done to find out the most frequent and life threatening reactions that develop during transfusion. Methods: A Cross sectional descriptive observational study was performed at a tertiary care centre. Patients of 18 years and older irrespective of sexes who received blood and blood products due to different reasons between April 2020 to September 2020 were included in this study. A total of 96 patients were included in the study. Results:In thisstudy 11(11.5%) out of 96 patients had transfusion reactions of different types .Febrile non haemolytic reaction was the highest with 8 patients (8.33%),followed by Allergic reaction in 2 patients(2.08%) and Acute haemolytic transfusion reaction in 1 patient (1.04%).Among them 7(63.6%) reactions occurred with whole blood , 2(18.2%) reactions occurred with red cell concentrate and 1 reaction occurred with Apheresis platelet (9.1%) and fresh frozen plasma(9.1%).Statistically significant association was found between duration of storage of blood and transfusion reaction. Conclusion: Febrile non haemolytic reaction was the commonest type of transfusion reaction found in this study and there was also statistically significant association between duration of storage of blood and transfusion reaction. Bangladesh J Medicine July 2022; 33(1) : 27-33

The 4-Year Experience with Implementation and Routine Use of Pathogen Reduction in a Brazilian Hospital

(1) Background: We reviewed the logistics of the implementation of pathogen reduction (PR) using the INTERCEPT Blood System™ for platelets and the experience with routine use and clinical outcomes in the patient population at the Sírio-Libanês Hospital of São Paulo, Brazil. (2) Methods: Platelet concentrate (PC), including pathogen reduced (PR-PC) production, inventory management, discard rates, blood utilization, and clinical outcomes were analyzed over the 40 months before and after PR implementation. Age distribution and wastage rates were compared over the 10 months before and after approval for PR-PC to be stored for up to seven days. (3) Results: A 100% PR-PC inventory was achieved by increasing double apheresis collections and production of double doses using pools of two single apheresis units. Discard rates decreased from 6% to 3% after PR implementation and further decreased to 1.2% after seven-day storage extension for PR-PCs. The blood utilization remained stable, with no increase in component utilization. A significant decrease in adverse transfusion events was observed after the PR implementation. (4) Conclusion: Our experience demonstrates the feasibility for Brazilian blood centers to achieve a 100% PR-PC inventory. All patients at our hospital received PR-PC and showed no increase in blood component utilization and decreased rates of adverse transfusion reactions.

The Significance of RHD Genotyping and Characteristic Analysis in Chinese RhD Variant Individuals

BackgroundRhD is the most important and complex blood group system because of its highly polymorphic and immunogenic nature. RhD variants can induce immune response by allogeneic transfusion, organ transplantation, and fetal immunity. The transfusion strategies are different for RhD variants formed by various alleles. Therefore, extensive investigation of the molecular mechanism underlying RhD variants is critical for preventing immune-related blood transfusion reactions and fetal immunity.MethodsRhD variants were collected from donors and patients in Zhejiang Province, China. The phenotypes were classified using the serologic method. The full coding regions of RHD gene were analyzed using the PCR-SBT method. The multiplex ligation-dependent probe amplification (MLPA) assay was used to analyze the genotype and gene copy number. SWISS-MODLE and PyMOL software were used to analyze 3D structures of RhD caused by the variant alleles. The effect of non-synonymous substitutions was predicted using Polymorphism Phenotyping algorithm (PolyPhen-2), Sorting Intolerant From Tolerant (SIFT), and Protein Variation Effect Analyzer (PROVEAN) software.ResultsIn the collected RhD variants, 28 distinct RHD variant alleles were identified, including three novel variant alleles. RH-MLPA assay is advantageous for determining the copy number of RHD gene. 3D homology modeling predicted that protein conformation was disrupted and may explain RhD epitope differential expression. A total of 14 non-synonymous mutations were determined to be detrimental to the protein structure.DiscussionWe revealed the diversity of RHD alleles present in eastern Chinese RhD variants. The bioinformatics of these variant alleles extended our knowledge of RhD variants, which was crucial for evaluating their impact to guide transfusion support and avoid immune-related blood transfusion reactions.

Cleavage of High Molecular Weight Kininogen and Bradykinin Release By Red Blood Cell Microvesicles As a Putative Mechanism for Hypotensive Transfusion Reactions

Background: Hypotensive transfusion reactions are adverse events typified by a sudden decrease in blood pressure that usually occurs within the first minutes after the initiation of a transfusion and resolves shortly after the transfusion is stopped. Due to current passive reporting practices, the incidence is likely underreported, but recent studies estimate an incidence of 1.3 cases per 10000 RBC units. The pathophysiology of these reactions are not fully understood. One hypothesis proposed is that increased bradykinin (BK), a nonapeptide released from cleavage of high molecular weight kininogen (HK), as seen with the use of negatively charged leukoreduction filters and the use of angiotensin-converting enzyme inhibitors, is a major contributor to the pathophysiology. We have recently demonstrated that red blood cell derived microvesicles (RBCMVs) from aging red blood cell (RBC) units are able to trigger thrombin generation via kallikrein activation - a predominant enzyme to cleave high molecular weight kininogen (Noubouossie, Blood, 2020). Thus, we hypothesize that the same RBCMVs would lead to bradykinin generation and might explain these hypotensive events. Objectives: To determine if RBC storage lesion-derived microvesicles are able to facilitate HK cleavage and BK release. Methods: RBCMVs were prepared from 4 recently expired RBC units (42 or 43 day old, AS-3 preserved, prestorage leukoreduced, all A+) via a series of centrifugations and washes. RBCMVs were quantified and characterized using nanoparticle tracking analysis. Obtained RBCMVs were first assessed for the capacity to initiate thrombin generation in microvesicle free human plasma via a substrate cleavage assay. Next, RBCMVs were added to a buffer reaction containing prekallikrein and HK, and kininogen cleavage was assessed via western blot. RBCMVs were also mixed with microvesicle-free human plasma and analyzed for evidence of kallikrein activation, cleavage of high molecular weight kininogen, and bradykinin production by ELISA. Cohn fractionation of plasma was used to enrich for BK. Results: RBCMVs were enumerated and concentrated to 7.5 ± 1.4 x 10 12 per mL (mean±SD size 160 ± 29µm). RBCMVs were able to initiate thrombin generation principally via contact pathway activation, independently of tissue factor. In a buffer system RBCMVs demonstrated activity to generate kallikrein with a sequential high molecular weight kininogen cleavage in a dose-dependent manner. Exclusion of kallikrein from the buffer system or addition of the small molecule inhibitor of kallikrein - ecallantide - halted cleavage of kininogen. A dose-dependent cleavage of high molecular weight kininogen indicated that RBCMVs could cause BK release in plasma; this was confirmed via an independent assay of Cohn -fractionated samples. Conclusions: Results of this current study demonstrate that RBCMVs are leading to high HK cleavage via kallikrein activation in vitro. We suspect that the same mechanisms could lead to BK generation in patients receiving older RBC units, possibly increasing the risk for hypotensive events from transfusion. Disclosures Karafin: Westat, Inc.: Consultancy. Key: Sanofi: Consultancy; BioMarin: Honoraria, Other: Participation as a clinical trial investigator; Takeda: Research Funding; Grifols: Research Funding; Uniqure: Consultancy, Other: Participation as a clinical trial investigator.