Comprehensive assessment of SARS-CoV-2 antibodies against various antigenic epitopes after naive COVID-19 infection and vaccination (BNT162b2 or ChAdOx1 nCoV-19).

Comprehensive assessment of SARS-CoV-2 antibodies against antigenic epitopes and cross-neutralization on variants is essential to monitor after infection or vaccination. From 32 COVID-19 patients and 40 vaccinated individuals [20 Oxford-AstraZeneca (AZ) and 20 Pfizer-BioNTech (BNT)], 348 serial sera are collected until 40 days after infection and 3 months after homologous booster vaccination. Antibody levels were monitored using a multiplex-bead assay including variant spike antigens, Roche (S1/RBD total) and a surrogate virus neutralization test (GenScript). Anti-S/S1/RBD levels were higher than anti-S2/N levels from 2 weeks after infection and were higher in severe infection (P < 0.05). Vaccination showed highest antibody levels after 1-month booster and had consistently high levels in the order of anti-full S, anti-RBD, anti-S1 and anti-S2. Infection induced higher anti-S2/N levels than prime vaccination (P < 0.05). Three months after BNT/BNT vaccination, antibody levels against S1/RBD and 23 variant antigens were higher than post-infection or AZ groups (P < 0.05). Regarding intraindividual changes from post-prime to post-boost vaccination, boost induced a 1.1- to 3.9-fold increase on multiplex-bead assay, 22.8- to 24.2-fold on Roche assay and 22.8- to 24.2-fold on GenScript assay. Post-prime levels by multiplex-bead assay predicted post-boost levels, but Roche and GenScript results were not predictive in the AZ group. The kinetics of SARS-CoV-2 antibody levels vary depending on the antigenic epitopes, assay kit, disease severity or vaccine type. Assessing seroconversion using multiplex-bead assays may contribute to monitoring the disease course, adjusting vaccination strategies, and accelerating vaccination efficacy.

Assessment of M-protein quantification using capillary electrophoresis and immunosubtraction-based integration in clinical samples with low M-protein concentrations.

OBJECTIVES: Quantification of monoclonal protein (M-protein) by serum protein electrophoresis (SPE) is indispensable for diagnosing and monitoring monoclonal gammopathies. However, quantification of small and beta migrating M-proteins is challenging because of overlapping non-immunoglobulin and/or polyclonal immunoglobulin protein fractions. We compared a new integration method based on immunosubtraction (IS-CE) using capillary zone electrophoresis (CZE) against the routine method, which includes a combination of perpendicular drop (0.4%), corrected perpendicular drop (1%) and tangent skimming (98.5%). DESIGN & METHODS: The proposed method of M-protein quantification involves calculating the difference in area under the curve between the SPE and a class-specific IS-CE trace. We analyzed the difference in estimated M-protein concentrations obtained with the new method and routine integration methods using 913 samples. For IgA M-proteins at < 10 g/L, the estimated M-protein concentrations were compared with the total IgA concentration. RESULTS: The median M-protein concentration of 913 consecutive samples was 6.2 g/L (IQR 2.1-14.3 g/L). The median and median % difference between the two integration methods was 0.68 g/L (IQR 0.01-1.55 g/L) and 10.9% (IQR 0.18-38.7%), showing a larger estimated M-protein concentration with the new method. More than 25% difference was observed in 38% of the samples and was associated with lower total protein concentration, lower M-protein concentration, IgA and IgM heavy chain isotypes, and beta- or beta-gamma migration. When 161 samples with IgA M-protein < 10 g/L were compared against total IgA concentration, the median bias of the new method was smaller compared to that of the existing method (-0.95 g/L vs. -1.3 g/L, P < 0.0001). CONCLUSIONS: The use of IS based integration using CZE and IS-CE is promising especially for small and beta migrating M-proteins.

Assessment of Rapid Optimized 96-well Tray Flow Cytometric Crossmatch (Halifax-FCXM) with Luminex Single Antigen Test.

INTRODUCTION: Flow cytometric crossmatch assay (FCXM) is a sensitive cell-based method for evaluating the presence of donor-specific antibodies (DSA) before transplantation. Recently, 96-well tray FCXM protocol (Halifax FCXM) with improved test efficiency has been introduced. The objective of the present study was to assess the performance of Halifax FCXM by correlating with DSA results based on single antigen bead (SAB) assays (virtual crossmatch, VXM). METHODS: A total of 341 FCXMs were evaluated for the detection of HLA-DSA. A positive VXM was defined as having at least one HLA - DSA (HLA-A, B, Cw, DR, DQB1) with ≥ 1000 MFI (mean fluorescence intensity) identified by SAB assay. RESULTS: Of a total 341 cases, 113 showed class I VXM (+) with class I DSA MFI ≥ 1000 exclusively against one or more donor HLA class I antigens (HLA-A, B, Cw), 72 had class I-/II + DSA, and 156 had VXM(-). Halifax T-FCXM showed a sensitivity of 87.6% (99/113) and a specificity of 98.2% (224/228) for detecting class I VXM (+). The concordance between T-FCXM and class I VXM was 94.7% (323/341). Halifax B-FCXM showed a sensitivity of 58.3% (42/72) and a specificity of 98.7% (154/156) for detecting class I-/II + DSAs. The concordance between B-FCXM and class I-/II + VXM was 86.0% (196/228). When we separately analyzed data, B-FCXM detected HLA-DR (+) (68.8%) and HLA-DQ (+) DSAs (71.0%) similarly (P > 0.05). T-FCXM detected 87.6%, 97.2%, and 98.2% of class I DSA-positive cases with MFI values (sumDSA) ≥ 1000, ≥ 3000, and ≥ 5000, respectively. B-FCXM detected 58.3% of class I-II + DSA -positive (≥1000) cases, but detected 76.7% (33/43) and 89.2% (33/37) of class I-II + DSAs if MFI values of sumDSA and immunodominant DSA (iDSA) were above 5000, respectively. Halifax FCXM had sensitivities of 91.5% and 96.2% for detecting VXM (+) having MFI values above 5000 for class I or class II sumDSA and iDSA, respectively. CONCLUSION: Halifax FCXM showed a good correlation, especially with SAB assay-based high MFI DSA or sumDSA. Concurrent application of FCXM with VXM can improve pre-transplant risk assessment and progress organ allocation efficiency.