Design and characterization of a microfluidic packed bed system for protein breakthrough and dynamic binding capacity determination

A 1.5 μL ion exchange chromatography column to accommodate resins used for biopharmaceutical processing has been designed to produce breakthrough curves and to quantify dynamic and maximum protein binding capacities. Channels within a glass chip were fabricated using photolithography and isotropic etching. The design includes a 1 cm long microfluidic column in which compressible, polydispersed porous agarose beads (70 μm mean diameter) were packed using a keystone method where particles aggregate in a narrow channel. The depth of the column is such that two bead layers exist. The fabrication technique used forms Cartesian geometries as opposed to circular cross sections found in standard columns. The voidage was therefore higher than standard values when measured by 3D confocal microscopy. In conjunction with microscopic techniques, the column allows visualization of events within the bed such as adsorption profiles that would otherwise be difficult to observe. In this work, the binding of fluorescently labeled protein during isocratic loading was used to generate breakthrough from the microcolumn. Useful breakthrough curves were achieved using mobile phase velocities from 60 to 270 cm h−1. Calculated dynamic binding capacities were compared well with previously published data on conventional scale columns. The microfluidic chromatography column described here thus allows study of process scale chromatography behavior at scales 20,000 times smaller than in current practice. The work described in this article is representative of the proof of principle of a potentially powerful tool for the generation of microfluidic process bed data for the biopharmaceutical industry. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009

[1]  Rajendrani Mukhopadhyay,et al.  When microfluidic devices go bad. How does fouling occur in microfluidic devices, and what can be done about it? , 2005, Analytical chemistry.

[2]  A. Lenhoff,et al.  Nondiffusive mechanisms enhance protein uptake rates in ion exchange particles , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[3]  Michael C. Flickinger,et al.  Encyclopedia of bioprocess technology : fermentation, biocatalysis, and bioseparation , 1999 .

[4]  P. Levison Large-scale ion-exchange column chromatography of proteins. Comparison of different formats. , 2003, Journal of chromatography. B, Analytical technologies in the biomedical and life sciences.

[5]  A. Staby,et al.  Comparison of chromatographic ion-exchange resins IV. Strong and weak cation-exchange resins and heparin resins. , 2005, Journal of chromatography. A.

[6]  Duncan Low,et al.  Future of antibody purification. , 2007, Journal of chromatography. B, Analytical technologies in the biomedical and life sciences.

[7]  P. Dephillips,et al.  Pore size distributions of cation-exchange adsorbents determined by inverse size-exclusion chromatography. , 2000, Journal of chromatography. A.

[8]  Experimental Van Deemter plots of shear-driven liquid chromatographic separations in disposable microchannels. , 2003, Journal of chromatography. A.

[9]  N Avdalovic,et al.  Ion chromatography on-chip. , 2001, Journal of chromatography. A.

[10]  Howard A. Chase,et al.  Modelling single-component protein adsorption to the cation exchanger s sepharose® FF , 1990 .

[11]  Nigel J. Titchener-Hooker,et al.  Effect of fouling on the capacity and breakthrough characteristics of a packed bed ion exchange chromatography column , 2006, Bioprocess and biosystems engineering.

[12]  N. Titchener-Hooker,et al.  Visualising fouling of a chromatographic matrix using confocal scanning laser microscopy , 2006, Biotechnology and bioengineering.

[13]  Steven A. Soper,et al.  Surface modification of polymer-based microfluidic devices , 2002 .

[14]  A. Liapis,et al.  Frontal chromatography of proteins. Effect of axial dispersion on column performance. , 1998, Journal of chromatography. A.

[15]  Elisabeth Verpoorte,et al.  An integrated fritless column for on-chip capillary electrochromatography with conventional stationary phases. , 2002, Analytical chemistry.

[16]  A. Lenhoff,et al.  Effects of ionic strength on lysozyme uptake rates in cation exchangers. I: Uptake in SP Sepharose FF. , 2005, Biotechnology and bioengineering.

[17]  G. Fasman,et al.  Practical Handbook of Biochemistry and Molecular Biology , 1989 .

[18]  Fahima Ouchen,et al.  An integrated solid‐phase extraction system for sub‐picomolar detection , 2002, Electrophoresis.

[19]  R. E. Oosterbroek,et al.  On-chip hydrodynamic chromatography separation and detection of nanoparticles and biomolecules. , 2003, Analytical chemistry.

[20]  Alois Jungbauer,et al.  Shallow Bed Adsorption: Theoretical Background and Applications , 2005 .

[21]  Quantitative magnetic resonance imaging of urea and lysozyme in protein chromatography. , 2004, Journal of chromatography. A.

[22]  N Gottschlich,et al.  Two-dimensional electrochromatography/capillary electrophoresis on a microchip. , 2001, Analytical chemistry.

[23]  Qualification of a chromatographic column: Why and how to do it , 2003 .

[24]  Martina Micheletti,et al.  Microscale bioprocess optimisation. , 2006, Current opinion in biotechnology.

[25]  Paul Watts,et al.  Micro reactors: principles and applications in organic synthesis , 2002 .

[26]  Jean M. J. Fréchet,et al.  Molded Rigid Monolithic Porous Polymers: An Inexpensive, Efficient, and Versatile Alternative to Beads for the Design of Materials for Numerous Applications , 1999 .

[27]  Daniel G Bracewell,et al.  An automated microscale chromatographic purification of virus‐like particles as a strategy for process development , 2007, Biotechnology and applied biochemistry.