This is a review discussing the production and properties of cryogels (from the Greek kappa rho iota sigma (kryos) meaning frost or ice), immobilization of ligands in cryogels and the application of affinity cryogels in bioseparation. Cryotropic gel formation proceeds in a non-frozen liquid microphase existing in the macroscopically frozen sample. Due to the cryoconcentration of gel precursors in the non-frozen liquid microphase, cryogelation is characterised by a decrease in the critical concentration of gelation and an increase in gelation rates compared with traditional gelation at temperatures above freezing point. Cryogels can be obtained through the formation of both physically and covalently cross-linked heterogeneous polymer networks. Interconnected systems of macropores and sponge-like morphology are typical for cryogels, allowing unhindered diffusion of solutes of practically any size. Most of the water present in spongy cryogels is capillary bound and can be removed mechanically by squeezing. The properties of cryogels can be regulated by the temperature of cryogelation, the time the sample is kept in a frozen state and freezing/thawing rates, by the nature of the solvent and by the use of soluble and insoluble additives. The unique macroporous morphology of cryogels, in combination with osmotic, chemical and mechanical stability, makes them attractive matrices for chromatography of large entities such as protein aggregates, membrane fragments, viruses, cell organells and even whole cells. Special attention is given to immunosorption of viruses on cryogel-based sorbents. As chromatographic materials, cryogels can be used both in bead form and as spongy cylindrical blocks (monoliths) synthesized inside the chromatographic column. The macroporous nature of cryogels is also advantageous for their application as matrices in the immobilization of biocatalysts operating in both aqueous and organic solvents. New potential applications of cryogels are discussed.
Macroporous gels (MGs) with a broad variety of morphologies are prepared using the cryotropic gelation technique, i. e. gelation at subzero temperatures. These highly elastic hydrophilic materials can be produced from practically any gel-forming system with a broad range of porosity extending from elastic and porous gels with pore sizes up to 1.0 microm to elastic and sponge-like gels with pore sizes up to 100 microm. The versatility of the cryogelation technique is demonstrated by use of different chemical reactions (hydrogen bond formation, chemical cross-linking of polymers, free radical polymerization) mainly in an aqueous medium. Appropriate control over solvent crystallization (formation of solvent crystals) and rate of chemical reaction during the cryogelation allows the reproducible preparation of cryogels with tailored properties. Different approaches, such as chemical modification of reactive groups, grafting of the pore surface with an appropriate polymer, or direct copolymerization with functional monomers are used for control of the surface chemistry of MGs. Typically, MGs with pore sizes up to 1.0 microm are produced in the shape of beads and MGs with pore size up to 100 microm are prepared as monoliths, discs, and sheets. The difference in porous structure of MGs defines the main applications of these porous materials. Elastic beaded MGs are mostly used as carriers for cell and enzyme immobilization or for capture of low-molecular weight targets from particulate-containing fluids in expanded-bed mode. However, the elastic and sponge-like MG monoliths with interconnected pores measuring hundreds of mum have been successfully used as monolithic columns for chromatography of particulate-containing fluids (crude cell homogenates, viruses, whole cells, wastewater effluents) and as three-dimensional scaffolds for mammalian cell culture applications.
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