Removal of β2-microglobulin (β2M) from the blood of patients suffering from kidney dysfunction is crucial to protect those individuals from getting the diseased state of dialysis-related amyloidosis. By harnessing the nucleation-dependent fibrillation process of amyloidogenesis, a β2M removal strategy has been proposed by preparing seed-conjugated polymer beads and assimilating soluble β2M to the fibrils on the surface at neutral pH. A novel peptide segment of β2M ranging from residue 58 to residue 67 (Lys-Asp-Trp-Ser-Phe-Tyr-Leu-Leu-Tyr-Tyr), which was capable of being fibrillated at neutral pH was isolated. Charge interaction between the positive N-terminal lysine and the negative C-terminal α-carboxylic group was demonstrated to be critical for the molecular self-assembly leading to the peptide fibril formation by favoring β-sheet conformation. Because the peptide fibrils were successful to seed intact β2M at neutral pH, the fibrils were immobilized on polymer beads of HiCore resins, and the resulting seed-conjugated beads were used to accrete intact β2M in the form of fibrils elongated on the bead surface. Its efficiency of the β2M removal was improved by placing the seed-immobilized beads in the middle of a continuous flow of the β2M-containing solution as practiced in the blood circulation during the hemodialysis. Therefore, this β2M removal system is suggested to exhibit high specificity, high binding capacity, and cost-effectiveness appropriate for eventual clinical application to remove β2M from the blood of renal failure patients.
Copyright © 2011 American Institute of Chemical Engineers (AIChE).