Background: Hyperhemolysis syndrome (HHS) is a severe delayed hemolytic transfusion reaction seen in sickle cell disease (SCD) patients, characterized by destruction of donor and recipient RBCs. It results in a drop in hemoglobin to below pretransfusion levels and frequently reticulocytopenia. Case Report: We report a case of a man in his thirties with SCD with a recent hospitalization 2 weeks prior for COVID-19. His red cell antibody history included anti-Fy(a) and warm autoantibody. At that time, he was given 2 units of RBC and discharged with a hemoglobin of 10.2 g/dl.He returned to the hospital approximately 1.5 weeks later with hemoglobin 6.0 g/dl and symptoms concerning for acute chest syndrome. Pretransfusion testing now showed 4+ pan-agglutinin in both gel-based and tube-based testing. Alloadsorption identified an anti-N and a strong cold agglutinin. Three least incompatible units were transfused to this patient over several days, with evidence of hemolysis. Further reference lab work revealed anti-Fy a , anti-Fy b , anti-Le a , anti-Le b , and an anti-KN system antibody. The patient's hemoglobin nadired at 4.4 g/dl. The patient was treated with a single dose of tocilizumab, his hemoglobin stabilized, and he was discharged. Discussion: We present a case of HHS proximate to recent SARS-CoV-2 infection with multiple allo and autoantibodies identified. Information on the relationship between SARS-CoV-2 infection and HHS is limited; however, it is possible that inflammation related to COVID-19 could predispose to HHS.Tocilizumab is an approved treatment for COVID-19. Additionally, tocilizumab appears to be a promising treatment option for patients with HHS.
Objectives Tissue carryovers are contaminants of surgical pathology cases in which extraneous tissue is incorporated into tissue blocks. Carryovers occur most frequently at the grossing or embedding stations, but little is published about them. We sought to analyze their transmission during transit to the histology lab. Methods Cassettes of friable donor tissue were mixed with cassettes of spongy recipient tissue in formalin-filled containers and agitated by shipment via pneumatic tube. The tissue cassettes were processed, embedded as blocks, and cut as usual. Liquid samples were prepared from the submission containers as well as from workstation submission containers and histology tissue processor waste. Results A high rate of contamination (14.9%) was observed under these artificial conditions. Friable donor tissue, including urothelium and colorectal adenocarcinoma, were promiscuous contaminants, as were placental villi. Fluid from submission containers showed viable tumor cells and fragments, which were also present in workstation submission containers and in tissue processor waste fluid. Conclusions This study implicates liquid transport media as a possible avenue of contamination during submission and transportation of tissue cassettes for histologic processing. Attention should be given to the friability of submitted tissue and physical agitation of the cassettes in transit. Such contaminants may be present in the fluid in tissue submission bins and in tissue processor fluid.
Objectives The sensitivity and specificity of clot lysis at 30 minutes after maximum clot strength (LY30), as measured by thromboelastography (TEG), for clinically significant hyperfibrinolysis have not been compared across the 2 US Food and Drug Administration–approved instruments (the TEG 5000 and TEG 6s [Haemonetics]). Methods We performed a retrospective, single-center analysis of these 2 instruments using the kaolin (CK) reagent. Results Local verification studies showed that the TEG 5000 and TEG 6s CK LY30 upper limits of normal (ULNs) were distinct (5.0% and 3.2%, respectively). Retrospective analysis of patient data showed that abnormal LY30 was 6 times more prevalent with the TEG 6s than with the TEG 5000 instrument. LY30 was a significant predictor of mortality with both instruments (TEG 6s: receiver operating characteristic [ROC] area under the curve [AUC] = 0.836, P ≤ .0001; TEG 5000: ROC AUC = 0.779, P = .028). The optimal LY30 cut point was determined based on these mortality data for each instrument. The TEG 6s showed superior mortality prediction than the TEG 5000 at lower LY30 levels (≥10%), with likelihood ratios of 8.22 and 2.62 for the TEG 6s and TEG 5000, respectively. Patients with a TEG 6s CK LY30 of 10% or higher were significantly more likely to die, receive cryoprecipitate, receive transfusions, or receive massive transfusion than patients with a TEG 6s LY30 of 3.3% to 9.9% (all P < .01). Patients with a TEG 5000 LY30 of 17.1% or higher were significantly more likely to die or use cryoprecipitate (P < .05); transfusion and massive transfusion protocol were not significantly different. Whole blood spiking studies showed that 70 ng/mL tissue plasminogen activator (tPA) achieved an average LY30 of approximately 10% for both instruments. Conclusions CK LY30 above the ULN is a sensitive but not specific cutoff for hyperfibrinolysis. At least moderately elevated CK LY30 carries more clinical portent on the TEG 6s instrument than on the TEG 5000. These TEG instruments are not sensitive to low concentrations of tPA.
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