Ex Vivo Biocompatibility of Avidin-Agarose: A New Device for Direct Adsorption of Biotinylated Antibodies from Human Whole Blood

: Radioimmunotherapy using radiolabeled antitumor antibodies (RAA) is limited by the toxicity of unbound antibodies in the circulation. Removal of excessive antibodies by affinity‐adsorption could therefore allow the administration of increased dosages of RAA while decreasing their adverse effects....

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Bibliographic Details
Published in:Artificial organs 2000-09, Vol.24 (9), p.696-704
Main Authors: Bosch, T., Lennertz, A., Duhr, C., Fink, E., Samtleben, W.
Format: Article
Language:English
Subjects:
Adsorption
Antibodies - blood
Antibodies, Neoplasm - blood
Anticoagulants - blood
Antithrombin III
Avidin - chemistry
Avidin-agarose
beta-Thromboglobulin - analysis
Biocompatibility
Biocompatible Materials - chemistry
Biotin - chemistry
Biotinylated antibodies
Blood Cell Count
Bradykinin - blood
Chromatography, Affinity
Citrates - blood
Complement C3a - analysis
Complement C5a - analysis
Hemolysis
Hemoperfusion
Hemoperfusion - instrumentation
Hemoperfusion - methods
Heparin - blood
Humans
Ligands
Pancreatic Elastase - blood
Peptide Hydrolases
Pressure
Radioimmunotherapy
Sepharose - chemistry
Thrombosis - prevention & control
Tumor antibodies
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Summary:: Radioimmunotherapy using radiolabeled antitumor antibodies (RAA) is limited by the toxicity of unbound antibodies in the circulation. Removal of excessive antibodies by affinity‐adsorption could therefore allow the administration of increased dosages of RAA while decreasing their adverse effects. Recently, avidin‐agarose (AA) minicolumns were used in animal experiments for the removal of biotinylated antibodies from whole blood exploiting the high affinity binding of biotin to avidin (pK 1015 M−1). This study was performed to evaluate the ex vivo biocompatibility of AA minicolumns with human blood. Ten ml AA minicolumns were perfused online ex vivo in the single pass mode with fresh blood from 8 healthy donors at a flow rate of 6.25 ml/min. The anticoagulation consisted of 0.5 IU heparin plus 0.0–2.1 mg citrate per ml of blood. In Part 1 of the study (40 min perfusion, n = 4), the optimal anticoagulation was found to be 0.5 IU heparin plus about 1 mg citrate per ml of blood. In Part 2 of the study, four 80 min test‐runs were performed. No signs of hemolysis were found, and the thrombogenicity of the AA gel was negligible. Cell counts and column inlet pressures remained constant; toward the end of the 80 min test‐runs, some activation of blood cells (elastase, β‐thromboglobulin), the complement system (C3a, C5a) and the plasmatic coagulation (thrombin‐antithrombin complex) was detectable. A moderate initial bradykinin release rapidly subsided to very low levels. In summary, AA minicolumns showed good biocompatibility upon contact with human whole blood and merit further investigation in a closed‐loop system for a potential application of direct tumor antibody removal by hemoperfusion.
ISSN:0160-564X
1525-1594
DOI:10.1046/j.1525-1594.2000.06568.x