Enzymatic synthesis of a catechin conjugate of polyhedral oligomeric silsesquioxane and evaluation of its antioxidant activity.

The antioxidant activity of catechin was amplified by conjugation with amine-terminated polyhedral oligomeric silsesquioxane (POSS) using horseradish peroxidase as catalyst. Compared to intact catechin, the scavenging activity of the POSS-catechin conjugate against superoxide anion was greatly improved. In addition, the conjugate strongly inhibited xanthine oxidase activity.

Gene expression control by temperature with thermo-responsive polymeric gene carriers.

A thermo-responsive copolymer, poly(N-isopropylacrylamide (IPAAm)-co-2-(dimethylamino)ethyl methacrylate (DMAEMA)-co-butylmethacrylate (BMA)), was synthesized and its in vitro gene transfection efficiency at different incubation temperatures was evaluated. A copolymer containing 8 mol% DMAEMA and 11 mol% BMA (P(IP-8DA-11BM)) had a lower critical solution temperature (LCST) at 21 degrees C, therefore the copolymer was insoluble above 21 degrees C and soluble below 21 degrees C. The LCST of P(IP-8DA-11BM) solution was not affected by the presence of salmon DNA. This copolymer was complexed with plasmid DNA, and the stability of the complex was analyzed by gel electrophoresis. DNA was completely retained in the complex, which was observed in the gel loading slot at 37 degrees C. At 20 degrees C, DNA was found to be partially dissociated from the complex by the appearance of the same band as DNA in the control experiment. These results clearly show that complex formation/dissociation was modulated by temperature alteration. The transfection efficiency of polymer-plasmid complexes was evaluated in COS-1 cells using pCMV-lacZ plasmid, encoding for beta-galactosidase as a reporter gene. The transfection efficiency of PDMAEMA homopolymer incubated at 37 degrees C for 48 h was greater than that incubated at 20 degrees C for 3 h and 37 degrees C for 45 h. In contrast, the transfection efficiency of P(IP-8DA-11BM) incubated at 20 degrees C for 3 h and 37 degrees C for 45 h was much higher than that incubated at 37 degrees C for 48 h. Such an increased transfection efficiency on lowering the temperature is considered to be due to appropriate formation/dissociation control of P(IP-8DA-11BM)-DNA complexes.

Transfection efficiency increases by incorporating hydrophobic monomer units into polymeric gene carriers.

The water soluble terpolymer, poly(N-isopropylacrylamide (IPAAm)-co-2-(dimethylamino)ethyl methacrylate (DMAEMA)-co-butylmethacrylate (BMA)) was synthesized, and its efficiency in in vitro gene transfection was evaluated. Copolymers with different compositions were synthesized by radical polymerization. For a series of copolymers containing 60 mol% of DMAEMA, the plasmid bands were retained within the gel loading slot, independent of polymer/plasmid weight ratios or BMA monomer content. In contrast, for a series of copolymers containing 20 mol% DMAEMA, plasmid bands of complexes were retarded with increasing weight ratios. For the copolymer with 10 mol% BMA content, the plasmid was completely retained within the gel loading slot. The transfection efficiency of polymer/plasmid complexes was evaluated in COS-1 cells using a pCMV-lacZ plasmid, encoding for beta-galactosidase as a reporter gene. Transfection efficiency of a series of copolymers containing 20 mol% of DMAEMA varied with BMA content. The transfection efficiency of the copolymers with 0, 2, and 5 mol% of BMA was low. The transfection efficiency of the copolymers with 10 mol% of BMA was about 2-fold higher than that of the PDMAEMA control homopolymer. The transfected cells were observed at a very wide range of polymer/plasmid weight ratios. The transfection efficiency of all copolymers containing 60 mol% of DMAEMA was lower than that of the PDMAEMA homopolymer.

Dual-stimuli-responsive drug release from interpenetrating polymer network-structured hydrogels of gelatin and dextran.

Interpenetrating polymer network (IPN)-structured hydrogels of gelatin (Gtn) and dextran (Dex) were prepared with lipid microspheres (LMs) as a drug microreservoir, and LM release from these hydrogels was examined in relation to their dual-stimuli-responsive degradation. A phase morphology in the IPN-structured hydrogels was varied with the preparation temperature, i.e. above or below the sol-gel transition temperature (Ttrans) of Gtn. The IPN-structured hydrogel prepared below Ttrans exhibited a specific degradation-controlled LM release behavior: LM release from the hydrogel in the presence of either alpha-chymotrypsin or dextranase alone was completely hindered, whereas LM release was observed in the presence of both enzymes. It is concluded that dual-stimuli-responsive drug release can be achieved by specific degradation of a particular IPN-structured hydrogel.

Double-stimuli-responsive degradation of hydrogels consisting of oligopeptide-terminated poly(ethylene glycol) and dextran with an interpenetrating polymer network.

Biodegradable hydrogels consisting of oligopeptide-terminated poly(ethylene glycol) (PEG) and dextran (Dex) with an interpenetrating polymer network (IPN) structure were prepared as models of novel biomaterials exhibiting a double-stimuli-response function. The IPN-structured hydrogels were synthesized by sequential cross-linking reaction of N-methacryloyl-glycylglycylglycyl-terminated PEG and Dex. In vitro degradation of the IPN-structured hydrogels was examined using papain and dextranase as model enzymes of hydrolyzing oligopeptide and Dex, respectively. Specific degradation in the presence of papain and dextranase was observed in the IPN-structured hydrogel with a particular composition of oligopeptide-PEG and Dex. This same hydrogel was not degraded by one of the two enzymes. The IPN-structured hydrogels were characterized by water content, thermal mechanical analysis, and wide-angle X-ray diffraction, and the results were compared with those of co-cross-linked hydrogels consisting of N-methacryloyl-glycylglycylglycyl-terminated PEG and methacryloyl Dex. The results suggest that the IPN-structured hydrogels contain physical chain entanglements between networks as well as chemical cross-linked networks. It is concluded that the double-stimuli-responsive degradation observed in the IPN-structured hydrogel is achieved by controlling the chain entanglements between the two biodegradable polymers. Such degradation property of the IPN-structured hydrogel can be useful as a fail-safe system for guaranteed drug delivery and/or medical micromachines.

[Recent trends in drug delivery systems using biomaterials].

Since the concept of sustained release of biologically active agents was established in 1970's, the sustained release has been examined by controlling the diffusion of drugs through polymeric matrices and/or the degradation of these polymers. Recently, drug release in proportion to internal or external stimuli has been getting important, which can be achieved by using stimuli-responsive polymeric materials. Majority of these polymers have been designed as to achieve their functions by changes in temperature, pH, glucose concentration, and the release of ribosomal enzymes. Especially, among those materials, biodegradable polymers have much potential for applications as implantable carriers for drug delivery system (DDS). In an auto feed-back drug delivery, several physiological changes in a living body can be utilized as the signal inducing polymer degradation and subsequent drug release. A hydrogel composed of hydrophilic biomaterials has been focused because of their high responsibility to the stimulus. In this paper, currently investigated DDS using hydrogels are reviewed with their strategies.