Transglutaminase‐modified wool keratin film and its potential application in tissue engineering

Transglutaminase (TGase) catalyzes the cross‐linking of many proteins and has been widely used to improve the properties of certain protein‐based materials. Keratin is considered as a promising biomaterial candidate following traditional chemical modification. In this study, the effect of TGase on the properties of a wool keratin film was investigated. The TGase‐modified film was applied to drug release and cell proliferation. Treatment with TGase (30 U/g keratin) for 18 h at 40°C increased the tensile strength of the film from 5.18 ± 0.15 MPa to 6.22 ± 0.11 MPa and decreased the elongation at break from 83.47 ± 1.79% to 72.12 ± 3.02%. The stability of the film in PBS and in artificial gastric juice was also improved. A rougher surface and a more compact cross‐section were observed by scanning electron microscopy photographs of the TGase‐treated film. SDS‐PAGE analysis confirmed that higher molecular weight proteins were formed in the TGase‐modified keratin solution and film. The results of the drug release assay using diclofenac indicated that both films with and without TGase treatment led to a high initial release in PBS, which was more constant in artificial gastric juice. The enzyme treatment led to a lower drug release rate from the film. Cell culture experiments suggested that the TGase‐mediated cross‐linked keratin film shows a good biocompatibility and that it can be used for tissue engineering applications.     

角质酶/角蛋白酶一浴法处理对羊毛性能的影响

采用T.fusca产角质酶以及Bacillus subtilis产角蛋白酶一浴法的方式处理羊毛,通过毡缩率、断裂强力、碱溶解度、上染速率、K/S值和接触角等指标考察了该处理对羊毛的改性效果,并运用XPS、氨基酸分析和SEM考察了其对羊毛结构与性质的影响。实验结果表明：经一浴法处理后,羊毛织物的毡缩率下降明显,达到机可洗要求;断裂强力下降较少,碱溶解度增加较少,上染速率提高,K/S值增加;XPS分析表明,经处理后羊毛纤维表面的元素含量变化较大;氨基酸分析表明,经处理后羊毛纤维中的胱氨酸质量分数有所降低;SEM显示,羊毛鳞片层大部分被剥除,综上可以说明角质酶/角蛋白酶的一浴法处理对羊毛具有明显的改性作用。     

Bio‐antifelting of wool based on mild methanolic potassium hydroxide pretreatment

Covalently bound lipids cover the wool surface and make enzymatic degradation of wool scales very difficult. In this paper, methanolic potassium hydroxide (MPH) pretreatment was used prior to enzymatic treatment of wool with protease, aiming at hydrolyzing the outmost lipids on the wool surface and promoting the subsequent proteolytic reaction. The efficacy of lipid removal from the fiber surface and the properties of the protease‐treated wool were evaluated. The results indicated that mild MPH pretreatment with 0.10 mol/L MPH for 10 min improved the wettability of the wool without adverse impacts on its mechanical properties. The wetting time and area shrinkage of the wool fabric reached 0.5 s and 5.6%, respectively, and the strength loss was within the acceptable range. Pretreatment with high concentrations of MPH for longer times led to significant damage to the wool fibers and caused heavy strength loss, without improving the antifelting properties after protease treatment. Thus, the combination of mild MPH and protease treatments endowed the wool with desirable properties in contrast to the treatment with protease alone.     

Simultaneous protease and transglutaminase treatment for shrink resistance of wool

A bioprocess for machine washable wool, combining the advantages of both protease and transglutaminase in a simultaneous enzymatic treatment has been developed. This process reduced the felting tendency of woven wool fabrics by 9% at the expense of only 2% weight and tensile strength loss. In contrast to previously described protease-based processes for shrink resistant wool, the anti-felting properties achieved in the simultaneous enzymatic treatment produced insignificant fibre damage, confirmed also by scanning electron images of the fabrics.     

Combined use of mild oxidation and cutinase/lipase pretreatments for enzymatic processing of wool fabrics

A cutinase from Thermobifida fusca WSH04 and two lipases, L3126 and Lipex 100L, were applied to the enzymatic pretreatment of wool fabrics followed by protease treatment, aiming at hydrolyzing the outmost bound lipids on the wool surface. A mild oxidation with 2 g/L hydrogen peroxide (30%) was selectively carried out before the enzymatic treatments. The cooperative actions of mild oxidation, cutinase and lipase pretreatments during wool processing were investigated. The results showed that lipase pretreatment alone had less impact on the wettability and anti‐felting ability of wool fabrics than cutinase treatment. Combined use of cutinase and lipase pretreatments did not evidently improve the properties of the wool fabric compared with the individual cutinase pretreatment. By contrast, mild oxidation slightly enhanced the activity of cutinase toward the wool surface and promoted the subsequent proteolytic reactions. The wetting time and contact angle of the protease‐treated fabric deceased to 1.2 min and 55°, respectively; the area shrinkage decreased to 3.1%, with an acceptable strength loss from 489 to 418 N. The changes in the cuticle scales of the wool fibers, confirmed by scanning electron microscopy, further proved the cooperative actions of mild oxidation and cutinase pretreatment during enzymatic wool processing.     

Physico-Mechanical Properties of Chemically Treated Bacterial (Acetobacter xylinum) Cellulose Membrane

Bacterial cellulose obtained through fermentation by the Acetobacter xylinum is of superior functional quality in comparison to plant cellulose. Various alkali treatment methods were used to process bio-chemically complex pellicle into a clean cellulose membrane/sheet. The effect of potassium hydroxide, sodium carbonate and potassium carbonate was found to be milder on the final cellulose product in contrast to the widely used sodium hydroxide treatment. These novel treatment methods also caused improvement in the tensile strength of the membranes in comparison to sodium hydroxide. The overall quality of the 0.1 M sodium carbonate- and potassium carbonate-treated cellulose was superior, as the membranes displayed maximum tensile strength and elongation next to the native membrane. The low tensile strength of sodium hydroxide-treated membrane is attributed to its higher swelling characteristics in alkali. Further, the low swelling property of sodium carbonate- and potassium carbonate-treated membranes resulted in their high oxygen transmission rates (low oxygen barrier). Hunter lab colour parameters were determined to assess the effect of different alkali treatments on the colour characteristics of the membranes. Further, based on the high mechanical strength and comparatively low oxygen transmission rates, the processed cellulose membranes may find application as a bio- packaging material for controlled atmosphere packaging, where hydrophilic membranes with high oxygen barrier and water vapour permeation are desirable.     

Effect of transglutaminase and 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide on the solubility of fish gelatin–chitosan films

The possibility of decreasing the water solubility of the films made from fish gelatin and chitosan by modification with TGase was investigated. The effectiveness of enzymatic treatment was also compared with chemical crosslinking using EDC. The treatment of the components with TGase in concentration of 0.2 mg/ml of the film-forming solution limited the solubility of the films at 25 °C from 65% to 28% at pH 6 and from 96% to 37% at pH 3. After 15 min of heating at 100 °C, the modified films were soluble in 23% at pH 6 and in 41% at pH 3. Further decrease of the solubility of the fish gelatin–chitosan films was achieved when enzymatic modification was conducted in the presence of 5–10 mM DTT; the solubility was about twice lower than that without DTT at both studied temperatures and pH values. Generally, the composite films modified with EDC in concentration of 30 mM were distinctly less soluble than films made from the components modified with TGase in the presence of DTT.     

Effect of Root Moisture Content and Diameter on Root Tensile Properties

The stabilization of slopes by vegetation has been a topical issue for many years. Root mechanical characteristics significantly influence soil reinforcement; therefore it is necessary to research into the indicators of root tensile properties. In this study, we explored the influence of root moisture content on tensile resistance and strength with different root diameters and for different tree species. Betula platyphylla, Quercus mongolica, Pinus tabulaeformis, and Larix gmelinii, the most popular tree species used for slope stabilization in the rocky mountainous areas of northern China, were used in this study. A tensile test was conducted after root samples were grouped by diameter and moisture content. The results showedthat:1) root moisture content had a significant influence on tensile properties; 2) slightly loss of root moisture content could enhance tensile strength, but too much loss of water resulted in weaker capacity for root elongation, and consequently reduced tensile strength; 3) root diameter had a strong positive correlation with tensile resistance; and4) the roots of Betula platyphylla had the best tensile properties when both diameter and moisture content being controlled. These findings improve our understanding of root tensile properties with root size and moisture, and could be useful for slope stabilization using vegetation.     

Effect of polysaccharide structure on mechanical and thermal properties of galactomannan-based films

Films were prepared from guar gum and locust bean gum galactomannans. In addition, enzymatic modification was applied to guar gum to obtain structurally different galactomannans. Cohesive and flexible films were formed from galactomannans plasticized with 20-60% (w/w of polymer) glycerol or sorbitol. Galactomannans with lower galactose content (locust bean gum, modified guar gum) produced films with higher elongation at break and tensile strength. The mechanical properties of films were improved statistically significantly by decreasing the degree of polymerization of guar gum with mannanase treatments (4 h) of 2 and 10 nkat/g, whereas 50 nkat/g produced films with low elongation at break and tensile strength. Galactomannans with approximately 6 galactose units per 10 mannose backbone units resulted in films with 2 peaks in loss modulus spectra, whereas films from galactomannans with approximately 2 galactose groups per 10 mannose units behaved as a single phase in dynamic mechanical analysis.     

New Enzyme-based Process Direction to Prevent Wool Shrinking without Substantial Tensile Strength Loss

In this paper a new enzymatic process direction is described for obtaining machine washable wool with acceptable quality. In general, application of protease enzyme technology in wool processing results in considerable loss of tensile strength by diffusion of the enzyme into the interior of wool fibers. To overcome this disadvantage enzymatic activity has been more targeted to the outer surface of the scales by improving the susceptibility of the outer surface scale protein for proteolytic degradation. This has been realized by a pretreatment of wool with hydrogen peroxide at alkaline pH in the presence of high concentrations of salt.     

Photo oxidation of rice starch II. Using a water soluble photo initiator

A new photo oxidation system was established when rice starch was oxidized using UV irradiation and 4-(trimethyl ammoniummethyl) benzophenone chloride (BP2) as a photo initiator. BP2 is a water soluble photo initiator. The slurry prepared for photo oxidation contained rice starch, water and BP2 only. No oxidizing agents were added. Parameters affecting the photo oxidation process, i.e. temperature, concentration of BP2, material:liquor ratio and irradiation time were determined. The produced oxidized starch was evaluated by measuring the carboxyl content, carbonyl content and apparent viscosity. The produced photo oxidized rice starch showed sound increase in the carboxyl and carbonyl contents and sharp decrease in the apparent viscosity. The produced photo oxidized starch was tested for its suitability as a sizing agent for cotton yarns. Native starch and oxidized starch, used as a sizing agent by Misr Company of Spinning and Weaving in El-Mahalla El-Kubra (Egypt), were used for comparison. Sized cotton yarns were evaluated by measuring the tensile strength, elongation at break and percent of size removal. Cotton yarns sized using the prepared photo oxidized rice starch showed higher tensile strength, elongation at break and percent of size removal compared with native starch and oxidized starch used by Misr Company of Spinning and Weaving.     

Improvement of shrink-resistance and tensile strength of wool fabric treated with a novel microbial transglutaminase from Streptomyces hygroscopicus

In this study, a novel microbial transglutaminase (MTG) from Streptomyces hygroscopicus WSH03-13 was applied in the processing of wool fabrics. The results indicated that MTG treatment could improve felting properties and decrease tensile strength loss of wool fabrics. For the wool fabrics used in this study, MTG treatment following chemical and protease pretreatment led to a 2.32% of area shrinkage and about 16% recovery in tensile strength based on the samples without MTG treatment. Moreover, a traditional resin treatment was compared with the role of MTG. Although the tensile strength of wool fabrics treated by MTG was lower than that treated by resin treatment, the fabrics had similar anti-felting properties, and the chemical oxygen demand of wastewater was only half of the latter.     

Immobilization of cellulases on the reversibly soluble polymer Eudragit S‐100 for cotton treatment

Cellulases can penetrate into the fiber, causing tensile strength loss of the cellulosic fibers or fabrics. To minimize the tensile strength loss, we have immobilized cellulases on Eudragit S‐100. The characteristics of covalent Eudragit cellulase were evaluated using gel filtration analysis and UV spectra. Gel filtration analysis revealed that the cellulases were covalently bound to the polymer. Covalent Eudragit cellulase was loaded with the enzyme of about 40% and had a relative activity about 80% at a Eudragit S‐100 concentration of 15 g/L. When cellulase is bound to the polymer, the solubility profile becomes similar to the one of Eudragit. In addition, the effects of the enzyme on the cotton yarns and fabric using cellulases have been investigated. Native and immobilized cellulases caused improvements in whiteness and wrinkle recovery angle of the fabric in comparison to the control samples. The bending stiffness results show that native and immobilized cellulase treated cotton fabric has an improved softness than the control samples. It was found that using the immobilized cellulase reduced the weight and tensile strength, because the hydrolytic attack is only limited to the surfaces of cotton fibers.     

Electron spin resonance study of melanin treated with reducing agents.

The electron spin resonances (ESR) of several native and modified melanins have been determined. Melanins isolated from black wool and synthesized from 3,4-dihydroxyl-L-phenylalanine (L-DOPA) and tyrosine all show similar ESR signals. Modification of the isolated melanins by treatment with reducing agents causes some lightening in color and slight changes in the ESR spectra. Lithium and liquid ammonia (Birch) reduction applied to melanins from wool and L-DOPA gave very different results, as reflected by ESR spectra, but in both cases the changes were much greater than those produced by other treatments. In general, reductive treatments in nonaqueous media in the presence of metals increase the free radical content and line width, whereas treatment in aqueous media resulted in decreased free radical content. These observations are consistent with a melanin pigment which is an irregular polymer and has unpaired electrons localized on different but similar monomer units.     

Transglutaminase mediated grafting of silk proteins onto wool fabrics leading to improved physical and mechanical properties

Transglutaminases have the ability to incorporate primary amines and to graft peptides (containing glutamine or lysine residues) into proteins. These properties enable transglutaminases to be used in the grafting of a range of compounds including peptides and/or proteins onto wool fibres, altering their functionality. In this paper we investigated the transglutaminase mediated grafting of silk proteins into wool and its effect on wool properties. A commercial hydrolysed silk preparation was compared with silk sericin. The silk sericin protein was labelled with a fluorescent probe which was used to demonstrate the efficiency of the TGase grafting of such proteins into wool fibres. The TGase mediated grafting of these proteins led to a significant effect on the properties of wool yarn and fabric, resulting in increased bursting strength, as well as reduced levels of felting shrinkage and improved fabric softness. Also observed was an accumulation of deposits on the surface of the treated wool fibres when monitored by SEM and alterations in the thermal behaviour of the modified fibres, in particular for mTGase/sericin treated fibres which, with the confocal studies, corroborate the physical changes observed on the treated wool fabric.     

Effects of cutinase on the enzymatic shrink-resist finishing of wool fabrics

A novel microbial cutinase from Thermobifida fusca WSH04 was applied in the pretreatment of wool fabrics followed by protease treatment, aiming at improving the wettability of the samples by hydrolyzing the outmost bound lipids in the wool surface. Cutinase pretreatment could increase the efficacy of the subsequent protease treatment by improving the wettability, dyeability, and shrink-resistance of the wool fabrics. The data obtained by the XPS method showed the changes of elemental concentration in the wool surface after cutinase pretreatment. Compared with the fabrics treated with hydrogen peroxide and protease, the combination of cutinase and protease treatments produced better results in terms of wettability and shrink-resistance with less strength loss. The anti-felting property of the fabrics treated with the enzymatic resist-shrink technique is very promising to meet the commercial standard.     

Treatment of wool fibres with subtilisin and subtilisin-PEG

In this work the diffusion of serine proteases into wool fabrics and yarns was studied. The proteases used were free subtilisin and subtilisin-PEG (the same enzyme that was covalently cross linked to polyethylene glycol). It is shown that the adsorption and diffusion is facilitated by the pre-treatment performed, being the alkaline surfactant washing and bleaching the most effective in what concerns enzyme adsorption. Furthermore, this study suggests that the diffusion of proteases into wool is dependent on the size of the protease. The free enzyme penetrates into wool fibre cortex while the modified bigger enzyme is retained only at the surface, in the cuticle layer. Also, proteins without proteolytic activity do not adsorb considerably on wool due to its hydrophobic nature, therefore the diffusion is facilitated by hydrolytic action.

These results have important practical implications for the establishment of enzymatic wool finishing processes, since they allow for control of the enzyme hydrolysis, which was the major drawback of this environmental friendly option to the conventional chlorine treatments.     

Characterization of Human Recombinant Transglutaminase 1 Purified from Baculovirus-infected Insect Cells

Transglutaminase 1 (TGase 1) is required for the formation of a cornified envelope in stratified squamous epithelia. Recombinant human TGase 1 expressed in baculovirus-infected cells was purified in a soluble form at the molecular mass of 92 kDa. Recombinant TGase 1 was susceptible to limited proteolysis by both μ- and m-calpains, the calcium-dependent intracellular cysteine proteases. Although the proteolysis did not induce the elevation of the specific enzyme activity of TGase 1, the requirement of calcium ion in the enzymatic reaction was reduced. Furthermore, the effects of GTP, nitric oxide, and sphingosylphosphocholine, known as regulatory factors for tissue-type isozyme (TGase 2), on the enzymatic activity of TGase 1 were investigated.     

Viscoelastic properties of plasticized methylcellulose and chemically crosslinked methylcellulose

Films of methylcellulose (MC), poly(ethylene glycol)400 (PEG400) plasticized MC, and MC gels (MC crosslinked with glutaraldehyde (GA)) were prepared by casting from aqueous solutions. The swelling test has shown that the MC gels were insoluble in water and that their crosslinking density increased with increasing GA and HCl concentrations. The effect of the addition of PEG400 or GA to MC was investigated through dynamic mechanical analysis (DMA). The DMA analysis of PEG400/MC blends has shown that PEG400 was compatible with MC and was an effective plasticizer since the curves of tan δ against temperature exhibited single peaks (corresponding to a single glass transition temperature), which were displaced to lower values with increasing PEG400 content. The thermogravimetric analysis (TGA) indicated that the thermal stability of MC was not affected by the chemical crosslinking. The tensile strength was slightly increased through crosslinking while the elongation was slightly decreased. The presence of moisture in MC hydrogels decreased the tensile strength and enhanced the elongation while the addition of PEG400 decreased the tensile strength but sharply increased the elongation.