Amphiphilic polymers with activities

Amphiphilic Polymers with Potent Antibacterial Activity, Chapter 11... 

Since the number of monomers, and thus the resulting polymer structures, are limited by any of the specific living polymerization techniques, appropriate combination of different polymerization mechanisms can lead to a variety of new and useful polymeric materials. Therefore combinations of controlled radical polymerizations and other polymerizations applied to synthesize block copolymers have been developed. Generally, polymers with active sites, such as carbon-halogen or nitroxide or dithioester terminal groups, are synthesized by other living polymerizations, and the product is further used to initiate the controlled radical polymerization. In many cases, this method is essentially a variant of the macroinitiator method discussed above. However, in some cases, these kinds of macromolecules do not act as initiators, and may act as transfer agents. For example, an AB-type amphiphilic block copolymer, CLB-2 was prepared by RAFT polymerization of 2-(N-dimethylamino)ethyl methacrylate... 

Adsorption on solid matrices, which improves (at optimal protein/support ratios) enzyme dispersion, reduces diffusion limitations and favors substrate access to individual enzyme molecules. Immobilized lipases with excellent activity and stability were obtained by entrapping the enzymes in hydrophobic sol-gel materials [20]. Finally, in order to minimize substrate diffusion limitations and maximize enzyme dispersion, various approaches have been attempted to solubilize the biocatalysts in organic solvents. The most widespread method is the one based on the covalent linking of the amphiphilic polymer polyethylene glycol (PEG) to enzyme molecules [21]. 

This subject can be considered in terms of five different types of molecules or materials (a) biologically inert, water-insoluble polymers (b) water-insoluble polymers that bear biologically active surface groups (c) water-swellable polymeric gels, or amphiphilic polymers that function as membranes (d) water-insoluble but bioerodable polymers that erode in aqueous media with concurrent release of a linked or entrapped bioactive molecule and (e) water-soluble polymers that bear bioactive agents as side groups. 

Oheme and co-workers investigated335 in an aqueous micellar system the asymmetric hydrogenation of a-amino acid precursors using optically active rhodium-phosphine complexes. Surfactants of different types significantly enhance both activity and enantioselectivity provided that the concentration of the surfactants is above the critical micelle concentration. The application of amphiphilized polymers and polymerized micelles as surfactants facilitates the phase separation after the reaction. Table 2 shows selected hydrogenation results with and without amphiphiles and with amphiphilized polymers for the reaction in Scheme 61.335... 

Figure 1 Schematic structures of micelle and liposome, their formation and loading with a contrast agent, (a) A micelle is formed spontaneously in aqueous media from an amphiphilic compound (1) that consists of distinct hydrophilic (2) and hydrophobic (3) moieties. Hydrophobic moieties form the micelle core (4). Contrast agent (asterisk gamma- or MR-active metal-loaded chelating group, or heavy element, such as iodine or bromine) can be directly coupled to the hydrophobic moiety within the micelle core (5), or incorporated into the micelle as an individual monomeric (6) or polymeric (7) amphiphilic unit, (b) A liposome can be prepared from individual phospholipid molecules (1) that consists of a bilayered membrane (2) and internal aqueous compartment (3). Contrast agent (asterisk) can be entrapped in the inner water space of the liposome as a soluble entity (4) or incorporated into the liposome membrane as a part of monomeric (5) or polymeric (6) amphiphilic unit (similar to that in case of micelle). Additionally, liposomes can be sterically protected by amphiphilic derivatization with PEG or PEG-like polymer (7) [1].

In addition to their traditional applications as surfactants, dispersants, etc., amphiphilic polymers have recently been attracting active interest in terms of their behavior at liquid-liquid, solid-liquid, and other interfaces (micellization, segmental conformation, etc.), along with their biocompatibility. In this section, amphiphilic block copolymers alone are briefly discussed. Graft and multiarmed polymers with amphiphilic arms will be treated later in this chapter (Section VI). 

C. M., Simpson, M., Ansari, A. M., Harris, T. M., and Ekwuribe, N. Structure-activity relationship of insulin modified with amphiphilic polymers. AAPS PharmSci 1(1 Suppl.), 1998. 

Artificial enzymes may be divided into two categories semisynthetic artificial enzymes and synthetic artificial enzymes. Semisynthetic artificial enzymes are partly prepared by biological systems. Catalytic antibodies are typical examples of semisynthetic artificial enzymes. Semisynthetic artificial enzymes are also prepared by modification of a known protein or enzyme at a defined site with a cofactor or new functional group. Synthetic artificial enzymes are prepared totally by synthetic methods. Synthetic artificial enzymes may be either relatively small molecules with well-characterized structures or macromolecules. The term syn-zymes has been coined to designate synthetic polymers with enzyme-like activities. In addition, synthetic artificial enzymes are also obtained with molecular clusters such as micelles and bilayer membranes formed by amphiphiles. 

TaM 7. Amphiphilic polymers (11) with relatively low degrees of functionality obtained via active ester synthesis (see Fig. 12)... 

Peptides exhibit the highest antimicrobial activities of amphiphilic polymers and also possess antibacterial, antiviral, antifungi and anticancer activities [30-32]. In view of the potential applications of peptides, we will now discuss the synthesis of some important antibacterial peptides. Gad-1 and Gad-2 are peptides with amino acid chains and are prepared using O-fluorenylmethyloxycarbonyl (Fmoc) chemistry. 

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