A novel technique for the separation of monocytes from human peripheral blood preparations has been developed. The technique is based on the use of expanded-bed adsorption and a solid perfluorocarbon derivatized with avidin or streptavidin for the indirect positive or negative capture of cells labeled with biotinylated monoclonal antibodies. The perfluorocarbon support was prepared and characterized and the contactor design and operating conditions, that enable cells to be selectively isolated, were investigated. Experiments consisted of applying an immunolabeled pulse of 1 x 10(8) peripheral blood mononuclear cells (PBMCs), isolated by density gradient centrifugation, directly onto a refrigerated expanded bed. The major cell types remaining were T-lymphocytes, B-lymphocytes, and monocytes. Monocytes could be positively adsorbed, following labeling with anti-CD14 mAb, with a clearance of up to 89% and a depletion factor of 7.6. They could also be "eluted" using mechanical shear, with a 77% yield of the applied cells at a purity of 90% and >/= 65% viability. Negative isolation of monocytes, following labeling of the other cells present with anti-CD2, CD7, CD16, CD19, and CD56 mAbs, resulted in lymphocyte depletions of up to 81% with a monocyte enrichment factor of 3.8 and purity of 71%. The monocyte viability in the flowthrough was assessed to be > 95%. This combination of expanded-bed adsorption and fluidizable affinity supports shows significant potential for the intensification of cell separations.
Integration of the chemical extraction of recombinant inclusion-body protein from Escherichia coli, and its recovery by metal-affinity expanded-bed adsorption (IMAC-EBA) under denaturing conditions, was investigated. The viral coat protein L1 with a hexa-histidine tag was expressed in Escherichia coli HMS174(DE3) as a model protein. Interference of released host DNA with adsorbent fluidization in the EBA step was solved by selective precipitation using spermine and low-speed centrifugation. However, the capacity and selectivity of the adsorbent for L1 remained lower than anticipated. The binding of L1 to immobilized Ni(2+) was therefore studied in detail using surface plasmon resonance (SPR). The Tris buffer and ethylene-diamine tetraacetic acid (EDTA) used in the extraction mixture were found to interfere significantly with the L1-Ni(2+) interaction. The SPR studies suggest that L1 binding could be improved by replacing the Tris buffer with HEPES and by adding CaCl(2) to inactivate the EDTA. The modified chemical extraction conditions resulted in effective L1 extraction from cytoplasmic inclusion bodies, at high cell density (OD(600 )= 80) and without the use of reducing agent, into a medium optimized for subsequent IMAC recovery. The modified buffer conditions resulted in an improved binding capacity and a good L1 purification factor (12.7) and recovery yield (71%). This work demonstrates that it is possible to reduce the complexity and hence the cost associated with traditional processes used to prepare purified denatured protein, ready for refolding, from cytoplasmic inclusion bodies.
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