Effect of gamma irradiation on immobilized trypsin

The effect of ionizing radiation of 0.05-10 Mrad on trypsin immobilized on dialdehyde cellulose was being studied. After irradiation the activity of native trypsin decreases by 25%, as compared with the initial, while the activity of immobilized trypsin remains constant. Before immobilization cellulose undergoes special pretreatment that leads to a decrease in the initial contamination. Some samples of modified cellulose were contaminated by staphylococcus culture (200,000 microbes per 0.2 g) and then exposed to irradiation of 0.05-0.4 Mrad. A distinct correlation between the irradiation dose (0.05-0.4 Mrad) and contamination of the object was registered.     

Lysozyme‐responsive polymer systems for detection of infection

There is a strong need for new point‐of‐care systems for the detection of wound infection. Overseen infections in chronic wounds induce severe complications, such as delayed healing and high risks for the patients, while time‐consuming common gold and silver standard methods for infection assessment cannot be implemented in home care units. This study demonstrates for the first time the between correlation of lysozyme activity and silver‐standard microbiological evaluation of wounds. Significantly higher (eightfold increase; p < 0.001) lysozyme activity in infected wounds was in accordance with increasing bacterial burden of infected wound fluids. Moreover, a two‐layer membrane‐based test system was developed providing visible results on infection in a short time (30 min) while avoiding any intermediate steps such as centrifugation. In the first layer of the system, a size exclusion membrane (1.2–8 μm cut‐off) retained labeled peptidoglycane while allowing only smaller fragments resulting from lysozyme hydrolysis to pass through. These fragments were then captured in a second layer, an anion‐exchanging diethylaminoethyl cellulose membrane, resulting in clearly visible color changes. Colorimetric measurements demonstrated significant differences (p < 0.001) and sixfold higher delta E values between infected and noninfected wound fluids. This system allows a quick and straightforward determination of the status of a wound. The colorimetric readout indicates the increased lysozyme activity in infected wound fluid.     

Covalent immobilization of a glucoamylase to bagasse dialdehyde cellulose

Cellulose fibres from bagasse were oxidized by sodium periodate in sulphuric acid media at positions 2 and 3 of the anhydroglucose unit to produce dialdehyde cellulose. The aldehyde groups of the dialdehyde cellulose were able to react with amino groups of a glucoamylase to form covalent bonds and result in a dialdehyde cellulose immobilized enzyme. The optimum pH of this immobilized enzyme and free enzyme were in the range of 3.0–5.0 and 3.5–5.0, respectively. The optimum temperature for both the free and immobilized enzymes was 60–65 °C. The relative remaining activity of the immobilized enzyme was 36% and its stability was very good, since it could be reused for over 30 cycles. Its activity decreased from the first to the seventh reuse cycles, due to the slow detachment of non-covalently bound enzyme. However, activity tended to stabilize after the seventh cycle of reuse, indicating very stable covalent binding between the enzyme and dialdehyde cellulose.     

Immobilization of cellulolytic and hemicellulolytic enzymes on inorganic supports

Commercial cellulase preparations from Trichoderma viride and Aspergillus niger were immobilized on porous silica glass and ceramics such as alumina and titania with titanium tetrachloride (TiCl(4)) and on their silanized derivatives with glutaraldehyde (GLUT). The amounts of the immobilized enzymes were in the range 10-50 mg/g carrier (dry) depending on the kind of carrier and immobilization method. Their activities toward carboxymethyl cellulose (CMC), xylan, aryl-beta-glucoside, and aryl-beta-xyloside were 3-53% of those of the native enzymes. The optimum pH of the enzymes shifted to the acidic side in most cases, whereas the optimum temperatures were nearly the same as those of native ones. The activity of immobilized enzyme preparations towards CMC did not change significantly during continuous operation over a periods of 60 days. Finally, xylan was hydrolyzed with the immobilized enzymes, and the sugars formed were investigated.     

Preparation of porous material based on alginic acid, containing immobilized terrilytin

A comparative study was conducted on immobilization of terrilytin on alginic acid by attaching the enzyme by ionic or covalent bonds and possible use of such compounds in preparing porous coatings for wound treatment. It was shown possible to prepare a coating with the enzyme activity after radiation sterilization equal to 80-85 per cent of the initial level. Medico-biological investigations proved that the use of the coating in treatment of purulent wounds was efficient.     

Activity and stability of glucoamylase preparations in different methods of immobilization

Catalytic activity and stability of glucoamylases immobilized by different methods (adsorption, covalent binding) are studied comparatively. The highest stability is shown to be obtained under covalent binding. The binding efficiency and immobilized glucoamylase properties depend on the nature of insoluble carrier and a purification degree of the enzyme preparations. The choice of the cross-linking agent promoting a binding between the enzyme and the carrier is very significant. The activity and stability of immobilized glucoamylases obtained when using different cross-linking agents rise in such a sequence: 2,4-toluylenediisocyanate, cyanurochloride, glutaric dialdehyde, gossypol. Catalytic properties and stability are determined for soluble and immobilized glucoamylase forms from different sources.     

Oxidative refolding of lysozyme assisted by DsbA, DsbC and the GroEL apical domain immobilized in cellulose

Expression of recombinant proteins in Escherichia coli often leads to formation of inclusion bodies (IB). If a recombinant protein contains one or more disulfide bonds, protein refolding and thiol oxidation reactions are required to recover its biological activity. Previous studies have demonstrated that molecular chaperones and foldases assist with the in vitro protein refolding. However, their use has been limited by the stoichiometric amount required for the refolding reaction. In search of alternatives to facilitate the use of these folding biocatalysts in this study, DsbA, DsbC, and the apical domain of GroEL (AD) were fused to the carbohydrate-binding module CBD_Cex of Cellulomonas fimi. The recombinant proteins were purified and immobilized in cellulose and used to assist the oxidative refolding of denatured and reduced lysozyme. The assisted refolding yields obtained with immobilized folding biocatalysts were at least twice of those obtained in the spontaneous refolding, suggesting that the AD, DsbA, and DsbC immobilized in cellulose might be useful for the oxidative refolding of recombinant proteins that are expressed as inclusion bodies. In addition, the spontaneous or assisted refolding kinetics data fitted well (r² > 0.9) to a previously reported lysozyme refolding model. The estimated refolding (k _N) and aggregation (k _A) constants were consistent with the hypothesis that foldases assisted the oxidative refolding of lysozyme by decreasing protein aggregation rather than increasing the refolding rate.     

Disorders of oxidizing metabolism as a criterion of evaluation of the course of wound healing in experimental animals]

The authors carried out 90 experiments in fertile male Wistar rats and 10 experiments in rabbits with noncomplicated and complicated (infectious) wounds. We have revealed in the first 24 hours the characteristic changes of pro- and antioxidation potentials and acid-alkaline condition of blood plasma. The increasing of specific activity of LPO product by 30-40% and the decreasing of hydroperoxides level in comparison with the initial levels of these indicators and the decreasing of blood pH point out the possibility of purulent inflammation development in postoperative wounds. We can use the special treatment of purulent inflammatory wounds in early stages of its development by the meaning of prognostication of wound healing that is very valuable in medical practice.     

Synthesis and properties of carrier-fixed enzymes. VII. Linking of glucoamylase to dialdehyde cellulose, carboxymethylcellulose hydrazide and carboxymethylcellulose azide]

Glucoamylase (alpha-1,4-glucan glucohydrolase, EC 3.2.1.3) has been covalently linked to dialdehyde cellulose resulting in an immobilized enzyme containing 0.98% protein and an activity of 4.5 mg of the native enzyme per g of matrix, i.e. 46% relative activity. The complex lost its activity in continuous and batch hydrolysis of starch at 55 degrees C down to a limit of 18% of its original value. In contrast, the activity of the complex did not change when working at a temperature of 25 degrees C. Glucoamylase-carboxymethylcellulose complexes synthesized via carboxymethylcellulose hydrazide and azide, in contrast to MAEDA und SUZUKI [1], showed only an activity of 1 mg of the native enzyme per g of matrix. We did not succeed in coupling periodate-oxidized glucoamylase to carboxymethylcellulose hydrazide because the enzyme used lost nearly all of its activity already during periodate oxidation.     

Changes in the lipid peroxidation activity and intensity of tissue respiration during healing of aseptic and infected wounds in animal experiments

The variance of lipid peroxidation (LPO) was studied by the concentrations of malonic dialdehyde (MDA) in the tissue of wound bed and blood serum on the model of surface musculocutaneous aseptic and infected wounds simulated in 250 rats. The speed of oxygen consumption by isolated wound tissue was determined simultaneously. It was stated that the time course of MDA concentration in wounds and sera as well as tissue respiration in animals with infected wounds differed from those in animals with aseptic wounds. In a whole, MDA levels were found to be higher in cases with infected wounds and of changeable character. The latter animals demonstrated less intensive respiration of granulation tissue. Correlation between the variance of tissue respiration and MDA levels was established as was that of LPO and respiration with the phases of wound process. The findings could be used for the development of pathogenetic therapy and evaluation of its efficacy.     

Preparation of immobilized alpha-amylase covalently attached to granular polyacrylonitrile

In this report, alpha-Amylase originating from Bacillus subtilis (liquefying type) was immobilized on partially imidoesterized polyacrylonitrile (PAN) by covalent bonding. For the preparation of immobilized alpha-amylase, which has a high activity and high stability to repeated use, the optimum conditions for the preparation reaction were investigated. The optimum conditions for the preparation reaction were quantified on the basis of the enzymatic activity, the preservation of the activity during repeated use in batch process and the protein content on the support. Further-more, enzymatic properties of immobilized alpha-amylase prepared at optimum conditions were compared with the native enzyme. The optimum temperature and reaction time for the imidoes-terification reaction were 30 degrees c and 6 h, respectively, whereas those of the amidinatin reaction were 30-40 degrees C and more than 3 h, respectively; the optimum pH range was 9-10. Immobilized alpha-amylase prepared at the optimum conditions was very stable against the repeated use and had more than 90% of relative to activity of the first use after the tenth procedure. The initial reaction rate of immobilized alpha-amylase was lower than native alpha-amylase, but same amount of reducing sugars were produced after the reaction passed for more than 90 min. The immobilized alpha-amylase was less stabel at the high temperature and the more basic media. However, after long incubation time, immobilized alpha-amylase was more stable than the native enzyme in exposure to heat and a storng base.     

Lysis ofMicrococcus lysodeikticus by lysozyme covalently immobilized on cellulose and polyacrylamide

Lysozyme immobilized on polyacrylamide beads or cellulose fibers is found to retain activity for hydrolysis of the cell walls of Micrococcus lysodeikticus. The immobilization on cellulose is somewhat reversible; the polyacrylamide immobilized lysozyme does not release any enzyme upon washing as evidenced by UV and lytic activity tests. The specific catalytic activity of the lysozyme-polyacrylamide system is found to decline as the density of derivatized surface groups is increased; a model of protein deactivation due to excess surface coupling is presented as a possible rationale for such specific activity variations.     

Immobilization of a soluble chemically thermostabilized enzyme

Cellobiase was coupled to a dialdehyde dextran by reductive alkylation in the presence of sodium cyanoborohydride. The resulting conjugate, obtained without loss of enzymic activity, presents properties of thermoresistance largely superior to those of native enzyme: the rate of inactivation is reduced compared to that of native enzyme and its optimal temperature of activity is 70-75 degrees C instead of 65 degrees C. Finally the conjugate presents increased longevity when subjected to experiments of operational stability; its hydrolytic activity is maintained at 60 degrees C in a 10% (w/v) cellobiose solution for more than 100 h whereas the native enzyme is inactivated after 45 h. The cellobiase-dextran conjugate was immobilized by covalent coupling on aminated silica by reductive alkylation in the presence of NaBH(3)CN. The characteristics of thermoresistance of this stabilized and immobilized conjugate were studied and compared to those of a preparation of native cellobiase immobilized on a silica support activated with glutaraldehyde. Analysis of the thermoresistance of these two cellobiase preparations clearly shows that immobilization has maintained and even enhanced their properties. In particular, the operational stability, measured at 68 degrees C on 10% (w/v) cellobiose shows an increased longevity of the stabilized and immobilized enzyme for 120 h compared to 60 h for the native immobilized enzyme. Two successive incubations of these cellobiase derivatives show that it is possible to obtain 2.5 times more glucose with the stabilized-immobilized enzyme than with the immobilized preparation. The procedure described above enables us to prepare a thermostabilized immobilized cellobiase.     

Study on the kinetics of isolation of trypsin immobilized on dialdehyde cellulose during hydrolytic destruction

The kinetics of isolation of trypsin immobilized on a dialdehyde cellulose carrier in buffer solutions with pH 7.0 and 8.0 was studied. The number of the aldehyde groups amounted to 15-60 per cent of the initial one. The kinetics of hydrolytic destruction of the collected samples with the immobilized trypsin and the carrier in buffer solutions with pH 7.0 and 8.0 was also studied. The constants of the rates of trypsin isolation from the materials and the constants of the rates of liberation into the buffer solutions of the compounds containing CO-groups were determined. The groups were used for estimating hydrolytic destruction of the materials and the time of complete destruction of the materials in the solutions.     

A stereocomplex platform efficiently detecting antigen-antibody interactions

Ultrathin poly(methyl methacrylate) (PMMA) stereocomplex films with macromolecularly double-stranded regular nanostructures were prepared by layer-by-layer assembly of isotactic and syndiotactic PMMAs on solid surfaces. Antibodies were immobilized through the Fc region-capturing protein A, which had been physically adsorbed on the complex film, and the binding of antigens to immobilized antibodies was quantitatively investigated by the quartz crystal microbalance technique. Greater amounts of protein A with native forms were adsorbed on the complex film than those on conventional single-component PMMA films. Antibodies with high target-binding activities were also immobilized on the complex film. A greater amount of antigens could be detected on the complex film. The activity of protein A was maintained on the complex for a long time even within a dried state. The mechanism for the preservation of protein native forms on the complex surface was speculated by analyzing the physical adsorption of proteins with various secondary structures. Stereocomplex films can be utilized as novel coating nanomaterials for efficiently detecting protein-protein interactions.     

Role of a microbial factor, necrotic tissue and a foreign body in the development of wound suppuration

The effect of microorganisms, necrotic tissues and a foreign body on the development of festering process in rat wounds was studied. It was found that the presence of necrotic tissues is the necessary and sufficient condition for a clinical manifestation of infection in rat wounds. Additional infection of the wounds and introduction of a foreign body did not appreciably change the clinical picture. A model is suggested of a festering wound in rats without artificial infecting. In the festering wound, one could observe the replacement of the gram-positive coccal microflora by the gram-negative one. Meanwhile the gram-positive coccal microflora was predominant in the non-festering wound. The level of potential biochemical indicators of infection in the blood of animals with festering wounds was higher than in the blood of those with non-festering wounds. The morphology, and the content of microbial cells, the content of nucleic acids, and total proteolytic activity in festering wound tissues were examined over time.     

Chimeric lactase capable of spontaneous and strong immobilization on cellulose and development of a continuous-flow system for lactose hydrolysis at high temperatures

Recombinant plasmids containing fusion proteins composed of two different modules were constructed and expressed in Escherichia coli. The modules encoded the lactase LacA (LacZ) from the thermophilic bacterium Thermoanaerobacter ethanolicus and the cellulase CelD, a cellulose-binding module (CBM) from Anaerocellum thermophilum. The CelD CBM provides a spontaneous and strong sorption of the fusion proteins onto a cellulose carrier. The enzymatic activities of both the free LacA protein and LacA-CelD CBM fusion proteins immobilized onto the cellulose carrier were assessed. The LacA activity of the fusion protein was dependent upon its position with respect to the CBM. The highest level of lactase activity and stability was observed when the lactase domain was localized at its N terminus. A continuous-flow column reactor of lactase immobilized on a cellulose carrier was constructed, and its activity was assessed. The lactose hydrolysis rate for a 150 mM (5%) solution at a flow rate of 1 reactor volume per min was 75%, which is a value optimal for further whey transformation into glucose/galactose syrup.     

Clinico-laboratory effectiveness of modern ointments with a polyethylene glycol base in the treatment of purulent wounds]

The 25-year experience with the underbandage treatment of soft tissue purulent wounds of various location and genesis with modern ointments with polyethylene glycol as the basis was analyzed. Levocin, levomecole, dioxycole, 5-percent dioxydinic, 1-percent iodopyronic, 0.5-percent quinifuryl and furagel ointments proved to preserve their high activity against aerobic grampositive and gramnegative flora. 10-percent mafenide acetate ointment had a high selective effect on Pseudomonas aeruginosa. The new ointments nitacid and streptonitole containing nitazole and white streptocide were highly active against both aerobic and anaerobic infections. The use of the ointments with the polyethylene glycol as the basis made it possible to decrease 2 times the period of the patient hospitalization in surgical units and to shorten the terms of the systemic antibacterial therapy. The marked therapeutic effect of such ointments due to their high dehydrating capacity and broad antibacterial spectrum enabled to consider them as the drugs of choice in the local treatment of purulent wounds during the 1st phase of the wound process, trophic and decubic ulcers, infected burns, diabetic and atherosclerotic gangrene, furuncles, carbuncles, mastitis, etc. The ointments in the water soluble vehicle can be as well used with success for the prophylactic treatment of infected wounds after the suture. The multitarget effect of the ointments in the water soluble vehicle and their ability to prevent severe purulent complications permitted to consider them as the 1st order drugs in cases of emergency.     

Comparison of adhesion of wound isolates of Staphylococcus aureus to immobilized proteins

AIMS: To determine the ability of 149 clinical isolates of Staphylococcus aureus from burns, other wounds and environmental isolates to adhere to immobilized proteins. METHODS AND RESULTS: The ability to bind to immobilized fibrinogen, fibronectin, laminin, collagen, IgG and lysozyme was studied using a microtitre plate assay. The strains were very diverse. Binding to fibrinogen was most frequent, followed by fibronectin, collagen and laminin. Binding to IgG and lysozyme was weak and few strains showed strong binding. Numerical analysis showed that 65% of the strains infecting burns had similar properties and bound to fibrinogen, fibronectin, collagen and IgG. The strains infecting other wounds had more variable characteristics. CONCLUSIONS: The ability to adhere to proteins is important in wound infection, but clinical isolates were diverse in their ability to bind to the proteins tested. Burn wounds were more likely to be infected with strains showing multiple binding characteristics. SIGNIFICANCE AND IMPACT OF THE STUDY: The study confirms the importance of adhesins in clinical infection.     

The action of gamma irradiation on terrilytin immobilized on cellulose-fiber materials

The effect of gamma-radiation on terrilytin, a proteolytic enzyme immobilized on modified and nonmodified cellulose materials was studied by EPR. Dialdehyde cellulose and graft copolymer of cellulose and polyacrylic acid were used as the modified cellulose materials. Dependence of the native and immobilized terrilytin activity and the content of free radicals in the irradiated samples on the irradiation dose was observed. It was shown that immobilization of the enzyme led to increasing of its stability to the effect of the ionizing radiation. This was due to transfer of the free valency from terrilytin to the carrying polymer which prevented radiation and chemical destruction of the enzyme. The proteolytic activity of native terrilytin subjected to gamma-irradiation markedly decreased because of intramolecular and intermolecular interactions during reactions of the terrilytin free radicals, since in this case there was no polymer as an acceptor of the enzyme free valency.