Selective enzymatic modification of wool/polyester blended fabrics for surface patterning

Prajapati, Chetna; Smith, Edward M.; Kane, Faith; Shen, Jinsong

doi:10.1016/j.jclepro.2018.11.079

Cited by 15 publications

(6 citation statements)

References 21 publications

(22 reference statements)

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“…In this study, the enzyme protease was employed to selectively modify a wool/polyester-blended fabric to impart decorative surface patterning [73]. A series of controlled experiments for studying the interaction between enzyme and substrate (a compound on which an enzyme exerts its catalytic effect) were undertaken to achieve either partial or complete removal of the dyed wool fibre component with a view to revealing undyed polyester yarns which formed part of the fabric blend, resulting in novel fading and differential fabric relief (Table 1).…”

Section: Colouration and Surface Patterning By Enzymatic Degradationmentioning

confidence: 99%

“…Results successfully demonstrated a diverse range of highly individual patterns could be generated with the use of varying resist techniques trialled with enzyme processing [70,73]. The resulting visual aesthetic qualities achieved were heavily governed by the techniques, which controlled the degree of liquor accessibility and penetration, and consequently the level of wool degradation or decolourization.…”

Section: Colouration and Surface Patterning By Enzymatic Degradationmentioning

confidence: 99%

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Innovative Technologies for Sustainable Textile Coloration, Patterning, and Surface Effects

Kane

Shen

Morgan

et al. 2020

Sustainable Textiles: Production, Processing, Manufacturing &Amp; Chemistry

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The environmental impact of textile dyeing and finishing is of paramount concern in the textile industry. Enzyme and laser processing technologies present attractive alternatives to conventional textile colouration and surface patterning methods. Both technologies have the capability to reduce the impact of manufacturing on the environment by reducing the consumption of chemicals, water and energy, and the subsequent generation of waste. Two emerging textile processing technologies, laser processing and enzyme biotechnology were investigated as a means of applying surface design and colour to materials with a focus on improving the efficiency and sustainability of existing textile design and finishing methods.Through industrial stakeholder engagement and interdisciplinary research involving textile design, fibre and dye chemistry, biotechnology and optical engineering, this design-led project brought together design practice and science with a commercial focus. Each technology was used to modify targeted material properties, finding and exploiting opportunities for the design and finishing of textiles. The work resulted in a catalogue of new colouration and design techniques for both technologies making it possible to achieve: selective surface pattern by differential dyeing, combined three-dimensional and colour finishing and novel colouration of textile materials.The chapter provides a literature review mapping the use of enzyme biotechnology and laser processing technology within textile design and manufacturing to date, identifying current and future opportunities to reduce environmental impacts through their application. The methodological approach, which was interdisciplinary and design-led, will be introduced and the specific design and scientific methods applied will be detailed. Each of the techniques developed will be discussed and examples of the design effects achieved will be presented. And, an indication of the reductions in chemical effluent efficiencies in resource use, and design flexibility in comparison with traditional textile colouration and surface patterning techniques will be given.

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Section: Colouration and Surface Patterning By Enzymatic Degradationmentioning

confidence: 99%

Section: Colouration and Surface Patterning By Enzymatic Degradationmentioning

confidence: 99%

Innovative Technologies for Sustainable Textile Coloration, Patterning, and Surface Effects

Kane

Shen

Morgan

et al. 2020

Sustainable Textiles: Production, Processing, Manufacturing &Amp; Chemistry

Self Cite

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“…Wool, being a renewable natural protein fibre, is an attractive alternative to petroleum-based fibre, such as polyester polymer, owing to its properties of warmness, skin-friendliness and abrasive resistance. 1 However, natural wool has poor dyeability and is susceptible to shrinkage during washing as a result of its surface dense scale layer. 2,3 To overcome these shortcomings, surface modification of wool is necessary.…”

Section: Introductionmentioning

confidence: 99%

Enhancing dye adsorption of wool by controlled and facile surface modification using sodium bisulphite

Jiang

Zhang

et al. 2021

Coloration Technology

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Wool is a natural biopolymer with special properties, including warmth retention and skin-friendliness. However, its application in the textile industry is limited by the scale layer that covers its surface, which prevents the efficient diffusion of dye into the interior of its fibres, and increases wool's susceptibility to shrinkage during washing. Here, dissolution with sodium bisulphite is used for wool surface modification. The properties of surface dissolved wool are comprehensively characterised, including strength loss, shrinkage rate and dyeability. The three-dimensional images indicated that scale layer was etched. Coupled with Fourier-transform infrared (FTIR) spectra, the test results of strength loss and shrinkage rate indicated that surface dissolution degree can be controlled by time and temperature, and that the process does not break the fibre's main body structure. Dyeability properties, including dye absorption rate, deepness and uniformity at a lower temperature were enhanced, indicating amenability to industrial production. Our findings highlight a novel, efficient method of modifying protein fibre surface for enhancing properties with potential for largescale application.How to cite this article: Jiang Z, Zhang Y, Zhang N, et al. Enhancing dye adsorption of wool by controlled and facile surface modification using sodium bisulphite.

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“…To overcome these drawbacks, diverse techniques, such as cationization, plasma, enzyme, gamma, and microwave treatments, were employed for pretreatment of various textile fibers [4,[10][11][12][13][14][15][16][17][18][19][20]. Fundamentally, the adhesion of natural dyes to natural fibers without any treatment, mordanting, or fixation is inferior [21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

“…Alum is the most abundant metal salt in the earth, which is commonly used and considered as a safe mordant [26]. On the other hand, a cost-effective substitution way to produce natural colorants is ecological enzymatic natural dyeing [13,[27][28][29][30][31][32] . Several studies have been reported on the enzymatic treatment of textile fibers to take advantage of their lower energy consumption and environmentally friendly processes in order to enhance dyeability, physical, and mechanical properties [23,[33][34][35][36][37][38][39][40].…”

Section: Introductionmentioning

confidence: 99%

Surface Functionalization of Wool via Microbial-Transglutaminase as Bio-Mordant to Improve Dyeability with Madder in the Presence of Alum

Pour

2020

Coatings

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Herein, the wool fabric was mordanted with alum, treated with microbial transglutaminase (m-TGase), and then dyed with madder. Different concentrations of alum and m-TGase were used to find out the optimum condition to achieve the best color after dyeing the wool fabrics with aqueous extract of madder. FT-IR spectroscopy and scanning electron microscopy (SEM) methods were applied to characterize the as-prepared samples. Contact angle measurements showed that the water uptake capability was increased in the case of the wool sample treated with alum and enzyme. Moreover, the samples were assessed for color strength (K/S) and color fastness. Our results showed that the optimal condition to get the highest color value was for the sample with 10% owf (of weight of fabric) alum and 5% owf m-TGase. Furthermore, it was found that there was a critical concentration for enzyme so that an increase in m-TGase amount would cause damage to the scales of fibers. The best condition of the dyeing process was discussed in this study, and also the proposed mechanism was presented. Indeed, treatment of wool with m-TGase led to a reduction in the amount of consumed alum, while investigations in color performances demonstrated the enhancement in color fastness, as well as color strength.

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Selective enzymatic modification of wool/polyester blended fabrics for surface patterning

Cited by 15 publications

References 21 publications

Innovative Technologies for Sustainable Textile Coloration, Patterning, and Surface Effects

Innovative Technologies for Sustainable Textile Coloration, Patterning, and Surface Effects

Enhancing dye adsorption of wool by controlled and facile surface modification using sodium bisulphite

Surface Functionalization of Wool via Microbial-Transglutaminase as Bio-Mordant to Improve Dyeability with Madder in the Presence of Alum

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