Posters

Monolithic chromatographic supports can efficiently be used for fast separation and purification of different types of molecules, both in the analytical and preparative scale. CIM Convective Interaction Media™ monolithic columns are macroporous polymeric supports that allow in-seconds separation of proteins and other biomolecules in gradient and isocratic modes.

In this work, the results showing the main characteristics of CIM™ columns are presented. The breakthrough curves at different flow rates were measured and it is shown that the dynamic binding capacity is practically unaffected by increased flow rates. The adsorption isotherm is almost rectangular exhibiting a highly favourable conditions for binding the tested components to the matrix. Furthermore, relatively high binding capacity is still maintained at elevated ionic strengths of the binding buffer. Finally, the HETP values of the components with different molecular masses are presented.

There are many different chromatographic supports on market. Although main part of them are particle shaped supports, the so-called monoliths are becoming increasingly more important. Particle based supports are commonly uniform-sized of some micron with high porosity. The pores are required to increase the specific surface area and, as a consequence, to increase the binding capacity. Since the pores are closed on one side, the liquid inside them is stagnant and the movement of molecules is governed by diffusion. Therefore, to obtain a good separation and a high binding capacity, low flow rates should commonly be applied. This results in flowdependent resolution of the separation and dynamic binding capacity.

In contrast to conventional porous particles the morphological characteristics of CIM supports are characterised by a single monolithic unit that contains pores, opened on both sides. These pores are highly interconnected forming a flow-through a network. All the mobile phase is forced to run through these open pores, therefore, the mass transfer between stationary and mobile phases is based on convective flow. One of the key features of monolithic units is their pore size distribution that should enable low back pressure at high throughputs together with high specific surface area, needed for high binding capacity.

In this work, dynamic characteristics of CIM disks bearing weak anion exchange groups for binding Bovine Serum Albumin (BSA) were studied. Reproducibility was checked and protein concentration as well as the flow rate were varied. Preliminary results confirm the flow independence of the dynamic binding capacity in the whole range of applied flow rates.

CIM (Convective Interaction Media) represent a new generation of chromatographic supports. In contrast to conventional particle supports, where the void volume between individual porous particles is unavoidable, CIM supports consist of a single monolith with open channels. In this way, molecules to be separated are transported into the pores by convection, resulting in short separation times.

CIMsupports proved to be very efficient for extremely fast separations of proteins in ion exchange, hydrophobic interaction and affinity chromatography mode. Recently, the successful separation of DNA as well as some smaller molecules like e.g. peptides and oligonucleotides were also performed.

All the above mentioned separations were carried out on an analytical scale with the use of 0.34 mL CIM discs. The scale-up of monolithic units was limited mainly due to the problems associated to the mechanical stability, poor sample distribution and higher backpressures. The change from the axial to radial flow enables the design of the so-called 8 and 80mLCIM tubes. They were basically designed for very fast purification of macromolecules.

In this work we present some basic characteristics of these newly developed units in terms of separation and binding capacity. In addition, some practical examples will be given and discussed as well.