Fabrication and characterization of patterned leather-like biomaterial derived from Brazilein/Glycerol-finished Bacterial Cellulose by using 3-in-1 textile finishing process

Phan, Hung Ngoc; Vu, Nguyen Cong; Bui, Huong Mai

doi:10.1007/s10570-023-05193-w

Cited by 12 publications

(6 citation statements)

References 63 publications

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“…Within the scope of footwear, the ubiquity of leather stems from its outstanding properties, however, its association to animal slaughtering and high pollution questions its sustainability as a raw material. Leather alternatives, such as polyurethane or synthetic textiles, equally pose a level of risk, especially surrounding disposal and biodegradability (Rathinamoorthy and Kiruba, 2020), whereas the sustainable advantage of biomaterials and BC's excellent properties targeting leather applications (Phan et al, 2023) make BC ideal for the realm of footwear. Although different, the properties of BC (Girard, Chaussé, Vermette, 2024;Phan et al, 2023) are comparably unique to leather, particularly regarding its textural singularity and full-bodied drape.…”

Section: Materials Propertiesmentioning

confidence: 99%

“…Leather alternatives, such as polyurethane or synthetic textiles, equally pose a level of risk, especially surrounding disposal and biodegradability (Rathinamoorthy and Kiruba, 2020), whereas the sustainable advantage of biomaterials and BC's excellent properties targeting leather applications (Phan et al, 2023) make BC ideal for the realm of footwear. Although different, the properties of BC (Girard, Chaussé, Vermette, 2024;Phan et al, 2023) are comparably unique to leather, particularly regarding its textural singularity and full-bodied drape. Footwear displays reduced degree of motion compared to garments, but enhanced nuance within the possible range of motion.…”

Section: Materials Propertiesmentioning

confidence: 99%

“…As "BC still faces obstacles in [ : : : ] functionalization" (Phan et al, 2023) its composite application may be more effective than its mono-material state in creating textile materials. Specifically, the possibility of reassembly of the cellulose fibres around a knitted scaffold following breakdown is targeted, as well as achieving voluminous forms necessary to footwear making through the utilisation of shrinkage of the cellulose during drying, as this process resembles the application of heat-setting to leather (Bayes, 2016).…”

Section: Materials Propertiesmentioning

confidence: 99%

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Fermenting knits: A material-driven exploration of knit-based bacterial cellulose biocomposite textile materials through fibre reassembly

De Lara

2024

Res. dir. Biotechnol. des.

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Environmental concerns surrounding textile production have increased the need and interest in developing material innovations and interdisciplinary approaches to offset this ecological impact. Bacterial cellulose is present in several industries, and its biologically produced form has shown potential use within fashion. Within the emerging field of biodesign, research surrounding bacterial cellulose textiles generally focuses on the initial sheeted growth, while alternative outputs and working methods remain scarce. Here, fibre reassembly is analysed by fully integrating broken down BC fibres with knitted structures. Material selection and working methods take a practice-led approach to experiment formulation in order to observe material behaviour as central to development. This project aims to create biocomposite textiles that enhance the properties of bacterial cellulose and expand its designable characteristics through low-tech working methods accessible from designerly backgrounds. The results are intended to inform further research in footwear design contexts, as basis to develop BC-based components. Experimentation shows BC fibres reassembled around the knitted structures, varying according to yarn choice and fermenting environment alteration. This demonstrates potential for material and methodology development while exploring co-design with living organisms. In the context of future applications, BC-based composite textiles can self-assemble at different growth stages, offering the possibility of material-driven approaches to spaces intersecting biology and design.

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Section: Materials Propertiesmentioning

confidence: 99%

Section: Materials Propertiesmentioning

confidence: 99%

Section: Materials Propertiesmentioning

confidence: 99%

See 1 more Smart Citation

Fermenting knits: A material-driven exploration of knit-based bacterial cellulose biocomposite textile materials through fibre reassembly

De Lara

2024

Res. dir. Biotechnol. des.

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“…, 2022; Phan et al. , 2023a, c). It is obvious that diet modification methods will yields great potentiality and sustainability for silk dyeing and finishing in the future.…”

Section: Introductionmentioning

confidence: 99%

Characterization of self-dyed silk yarn with Rhodamine B dye for fashion applications

Tran

Hung

Hoang

et al. 2023

IJCST

Self Cite

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PurposeThe textile industry has consumed large quantities of water and discharged large volumes of wastewater in the dyeing process. The study aims to characterize self-dyed silk with Rhodamine B (RhB) for fashion applications to reduce textile hazards to the environment and increase the added value of silk.Design/methodology/approachBombyx mori was fed with RhB-colored mulberry leaves (1500 ppm). The effects of self-dyeing were investigated via color strength K/S, Fourier-transform infrared spectroscopy (FT-IR), scanning electron microscope, X-ray diffraction, tensile strength, color fastness to washing, rubbing, perspiration and light.FindingsSelf-dyed silk possesses effective coloration and impressive color fastness (4–5/5), higher crystalline index (CrI) (73.26 ± 2.28%), less thermal stability and tenacity, slight change in amino acid composition compared with the pristine and no existence of harmful aromatic azo amines and arylamine salts.Practical implicationsThe application of self-dyed silk with RhB dye has expanded new technology into fashion industry, contributing partly to economic growth and adding value to silk in the global supply chain. Besides, the self-dyeing will yield practical values in the reduction of dyeing discharge in textile industry.Originality/valueSelf-dyed silk was characterized for textile applications in comparison with pristine silk in terms of color strength and fastness as well as determined its polymeric properties relating to crystallinity, morphology, chemical composition, tensile properties and thermal stability which have not been investigated before.

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“…Additionally, from a physical point of view, the web-shaped sequence of monomeric units linked by β-1,4-glycosidic bonds might contribute to a high mechanical strength, an elevated degree of polymerisation, an increased crystallinity index (80–90%), tensile strength, and water-holding capacity compared to plant cellulose [ 19 , 20 , 21 , 22 ]. Therefore, BC fits not only biomedical solutions (e.g., for wound healing [ 23 ], antibacterial coatings [ 24 , 25 ], controlled drug delivery [ 26 ], cancer treatment [ 27 ], tissue engineering [ 28 ], and cell cultures [ 29 ]) but also finds some bulk applications [ 19 ], e.g., in the textile industries [ 30 , 31 , 32 , 33 , 34 ]. Consequently, selected technological solutions involving the use of bacterial cellulose in the textile and leather industries are presented below.…”

Section: Introductionmentioning

confidence: 99%

Ecologically Modified Leather of Bacterial Origin

Lisowski,

Bielecki,

Cichosz

et al. 2024

Materials

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The research presented here is an attempt to develop an innovative and environmentally friendly material based on bacterial nanocellulose (BNC), which will be able to replace both animal skins and synthetic polymer products. Bacterial nanocellulose becomes stiff and brittle when dried, so attempts have been made to plasticise this material so that BNC can be used in industry. The research presented here focuses on the ecological modification of bacterial nanocellulose with vegetable oils such as rapeseed oil, linseed oil, and grape seed oil. The effect of compatibilisers of a natural origin on the plasticisation process of BNC, such as chlorophyll, curcumin, and L-glutamine, was also evaluated. BNC samples were modified with rapeseed, linseed, and grapeseed oils, as well as mixtures of each of these oils with the previously mentioned additives. The modification was carried out by passing the oil, or oil mixture, through the BNC using vacuum filtration, where the BNC acted as a filter. The following tests were performed to determine the effect of the modification on the BNC: FTIR spectroscopic analysis, contact angle measurements, and static mechanical analysis. As a result of the modification, the BNC was plasticised. Rapeseed oil proved to be the best for this purpose, with the help of which a material with good strength and elasticity was obtained.

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Fabrication and characterization of patterned leather-like biomaterial derived from Brazilein/Glycerol-finished Bacterial Cellulose by using 3-in-1 textile finishing process

Cited by 12 publications

References 63 publications

Fermenting knits: A material-driven exploration of knit-based bacterial cellulose biocomposite textile materials through fibre reassembly

Fermenting knits: A material-driven exploration of knit-based bacterial cellulose biocomposite textile materials through fibre reassembly

Characterization of self-dyed silk yarn with Rhodamine B dye for fashion applications

Ecologically Modified Leather of Bacterial Origin

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