Cation exchange frontal chromatography for the removal of monoclonal antibody aggregates.

A low ligand density cation exchange (CEX) chromatography resin, Eshmuno® CP-FT resin, was investigated for the removal of aggregates from monoclonal antibody (mAb) feeds using a continuous loading process. Removing mAb aggregates with a CEX resin using continuous loading is advantageous relative to a bind/elute loading process, because the resin can use nearly its full capacity to bind the aggregates enabling much higher loadings. The removal of mAb aggregates with Eshmuno® CP-FT resin using a continuous loading process was found to be consistent with a frontal chromatography mechanism where the mAb monomer initially binds to the column and is subsequently displaced by dimers and higher molecular weight aggregates. The removal of mAb aggregates with Eshmuno® CP-FT resin using a continuous loading process was compared with six other commercially available strong CEX chromatography resins and found to correlate with their ionic densities, but not their mAb static binding capacities. The influence of pH, conductivity, residence time, and mAb concentration on the removal of aggregates with Eshmuno® CP-FT resin using a continuous loading process was also investigated. Finally, the percentage of aggregates in a mAb feed was varied to examine the effect on the removal of aggregates with Eshmuno® CP-FT resin using a continuous loading process.

Flow-Induced Crystallization of Collagen: A Potentially Critical Mechanism in Early Tissue Formation.

The type I collagen monomer is one of nature's most exquisite and prevalent structural tools. Its 300 nm triple-helical motifs assemble into tough extracellular fibers that transition seamlessly across tissue boundaries and exceed cell dimensions by up to 4 orders of magnitude. In spite of extensive investigation, no existing model satisfactorily explains how such continuous structures are generated and grown precisely where they are needed (aligned in the path of force) by discrete, microscale cells using materials with nanoscale dimensions. We present a simple fiber drawing experiment, which demonstrates that slightly concentrated type I collagen monomers can be "flow-crystallized" to form highly oriented, continuous, hierarchical fibers at cell-achievable strain rates (<1 s(-1)) and physiologically relevant concentrations (∼50 µM). We also show that application of tension following the drawing process maintains the structural integrity of the fibers. While mechanical tension has been shown to be a critical factor driving collagen fibril formation during tissue morphogenesis in developing animals, the precise role of force in the process of building tissue is not well understood. Our data directly couple mechanical tension, specifically the extensional strain rate, to collagen fibril assembly. We further derive a "growth equation" which predicts that application of extensional strains, either globally by developing muscles or locally by fibroblasts, can rapidly drive the fusion of already formed short fibrils to produce long-range, continuous fibers. The results provide a pathway to scalable connective tissue manufacturing and support a mechano-biological model of collagen fibril deposition and growth in vivo.