Isoagglutinin reduction by a dedicated immunoaffinity chromatography step in the manufacturing process of human immunoglobulin products.

BACKGROUND: The passive transfer of antibodies specific to blood groups A and B (also called isoagglutinins) contained in immunoglobulin (Ig)G products for intravenous administration (IVIG) is believed to be largely responsible for rare but sometimes serious IVIG-related hemolytic events. We present in this work a modification of the manufacturing process of Privigen-a 10% l-proline-stabilized IVIG product-that allows extensive reduction of isoagglutinin concentrations in the final product. STUDY DESIGN AND METHODS: An additional immunoaffinity chromatography (IAC) step was introduced toward the end of the manufacturing process of Privigen. Isoagglutinin titers were measured using the indirect agglutination method and a published flow cytometry-based binding assay. Quality attributes, such as microorganism counts and concentration of endotoxins, IgG, IgA, IgM, aggregates, and so forth were measured using standardized procedures. RESULTS: The introduction of an IAC step in the manufacturing process of Privigen resulted in an 88% to 90% reduction in isoagglutinins between the feed of the chromatography column and the flow-through fraction. All other product quality attributes measured were nearly identical before and after IAC. This process modification resulted in a three-titer-step reduction in isoagglutinin levels in the final IgG product compared to Privigen lots produced by the unmodified process. CONCLUSION: Introducing an isoagglutinin-specific IAC step in the manufacturing process of Privigen is an efficient strategy for reduction of anti-A and anti-B titers. Such reductions might help minimize the risk of hemolytic events in patients receiving IVIG therapy.

Donor screening reduces the isoagglutinin titer in immunoglobulin products.

BACKGROUND: Hemolysis reaction is a rare class effect of therapy with intravenously administered human normal immunoglobulin (IVIG). Anti-A/B isoagglutinins (isohemagglutinins) originating from donor plasma are considered a probable risk factor for hemolysis. We hypothesized that screening and exclusion of plasma obtained from donors with high isoagglutinin titers from the manufacturing process would produce a meaningful reduction of anti-A/B isoagglutinin titers of the final IVIG product. STUDY DESIGN AND METHODS: A donor screening method for anti-A isoagglutinins using an automated indirect agglutination test (IAT) in gel cards was developed. Industry-scale donor plasma pools and final IVIG product were prepared according to the manufacturing process of Privigen (human 10% liquid IVIG). Anti-A/B isoagglutinin levels were measured by IAT, direct agglutination test, and a flow cytometry-based assay. RESULTS: Screening of plasma from 705 randomly selected donors identified 6.8% donors with high anti-A isoagglutinin titers in plasma. Exclusion of plasma from these donors resulted in a one-titer-step reduction of anti-A isoagglutinin in laboratory-scale pooled plasma. The same donor screening method applied to industry-scale production resulted in exclusion of 5.1% of donors and produced a one-titer-step reduction of both anti-A and anti-B isoagglutinin titers in the final IVIG product. CONCLUSION: Anti-A/B isoagglutinin titers in IVIG products can be reduced on an industrial scale through implementation of anti-A donor screening, which may lower the risk of hemolysis after IVIG therapy.

Isoagglutinin Reduction in Human Immunoglobulin Products by Donor Screening.

INTRODUCTION: Hemolysis is considered a class effect and a rare adverse event that can occur following therapy with human normal immunoglobulin for intravenous administration [i.e., intravenous immunoglobulin (IVIG)]. Anti-A/B isoagglutinins (also referred to as isohemagglutinins) originating from donor plasma are present in polyvalent immunoglobulin G (IgG) products and are considered a probable risk factor for hemolysis. We hypothesized that, by excluding plasma from donors with high isoagglutinin titers, the final IVIG product would have a meaningful reduction in anti-A/B isoagglutinin titers. METHODS: A method for screening donor plasma for anti-A isoagglutinins using an automated indirect agglutination test (IAT) was developed. A cut-off for donor plasma exclusion was defined. Industry-scale donor plasma pools and final IVIG product were prepared according to the manufacturing process of Privigen(®) (CSL Behring, Berne, Switzerland; human 10% liquid IVIG). Anti-A/B isoagglutinin content in pooled plasma and final IVIG product was measured by IAT, direct agglutination test, and a flow cytometry-based assay [fluorescence-activated cell sorting (FACS) anti-A]. RESULTS: Screening of plasma from 705 donors identified 48 (6.8%) donors with high anti-A isoagglutinin titers in plasma (IAT agglutination score ≥2+ in a 1:200 pre-dilution). Exclusion of plasma from these donors resulted in a one-titer-step reduction of anti-A isoagglutinin in pooled plasma, confirmed by a twofold anti-A isoagglutinin concentration reduction measured by FACS anti-A (1,352 vs. 2,467 µg/g IgG). When the same screening and exclusion were applied to industrial-scale plasma pools (resulting in the exclusion of plasma from 5% of donors), anti-A isoagglutinins were reduced by one titer step in the final IVIG product. Anti-B isoagglutinins were also reduced by one titer step, as many donors with high anti-A isoagglutinins also have high anti-B. CONCLUSION: Reduction of anti-A/B isoagglutinin titers in IVIG products on an industrial scale is feasible through implementation of anti-A donor screening, which may reduce the risk of hemolysis following IVIG therapy.