Search Results (96)

In this study, the interfacial phenomena of cotton/polyester blended fabric modified with enzymes and chitosan were investigated. Enzymatic pretreatments (bioactivation) were carried out using a pectinase complex (Biosol PRO), an esterase complex (Texazym PES), and a combination of both. Bioactivation aimed to activate the surface and improve interfacial properties, primarily the hydrophilicity of the polyester component in the blend. For the functionalization of bio-activated blended fabrics, a homogenized chitosan solution in a 3% acetic acid was prepared and applied in a pad–dry–cure process. Changes after enzyme bioactivation, chitosan functionalization, and three washing cycles were monitored by interfacial phenomena—including zeta potential, isoelectric point (IEP), specific surface charge, and contact angle, as well as wetting time and maximum wetted radius—measured using a Moisture Management Tester (MMT). Mechanical and spectral properties of fabrics and antimicrobial efficacy were determined as well. Although esterase and pectinase act on different components of the fabric, both contribute to improved fabric properties, especially when used together. The presence of chitosan on the fabric after three washing cycles was confirmed on enzyme-bioactivated fabrics by zeta potential, IEP, and specific surface charge. The antimicrobial activity was confirmed as well. The best results were obtained after functionalization with chitosan on the esterase-bioactivated surface. Overall, these treatments provide flexible and mechanically stable functionalization, demonstrating both antimicrobial effectiveness and washing stability, with the possibility of easy implementation in the textile industry. Full article

Textile materials represent a versatile class of engineering substrates widely used in apparel, domestic products, and medical protective systems. Despite their extensive application, large-scale textile production has seen limited integration of fundamentally new functionalization strategies. In recent years, however, advances in materials science have enabled the development of textiles with tailored electrical, adaptive, and biological functionalities. This review summarizes recent progress in the functionalization of textile materials with a focus on approaches relevant to engineering and industrial implementation. Particular attention is given to conductive textiles designed for operation under extreme environmental conditions, including low-temperature climates. Methods for integrating electrically conductive elements into fibrous structures are discussed, highlighting their potential for sensing, thermal regulation, and energy-related applications such as powering portable electronic devices. Inkjet printing is presented as a scalable technique for high-resolution deposition of conductive patterns while preserving the mechanical integrity and aesthetic properties of textile substrates. In addition, adaptive and stimuli-responsive textile systems are reviewed, including materials capable of responding to thermal, optical, or chemical stimuli, with applications in camouflage, wearable systems, and multifunctional surfaces. The review further addresses the development of bioactive textiles, emphasizing antibacterial functionalization using organic and inorganic agents to mitigate the spread of pathogenic microorganisms. The relevance of such materials has been underscored by recent global viral outbreaks. Overall, this work aims to provide a materials science perspective on emerging textile functionalization strategies and to facilitate the transition of these technologies from laboratory-scale research to practical engineering applications. Full article

Given the increasingly stringent environmental standards mandated today, the functionalization of textile materials using natural biopolymers and plant extracts represents an environmentally acceptable alternative to traditional synthetic agents. To obtain functionalized viscose fabric, a pretreatment process involving periodate oxidation followed by chitosan deposition was performed. Chitosan provides enhanced biological properties due to the presence of amino groups, which enable its deposition and the application of pomegranate peel (Punica granatum L.) extract during functionalization. Pomegranate peel extract contains a large number of bioactive compounds that further enhance the antibacterial and antioxidant activities of the functionalized viscose fabric. Changes in surface chemistry, morphology, and biological properties after functionalization and up to five washing cycles were followed by FTIR spectroscopy, zeta potential measurements, SEM, and determination of antibacterial and antioxidant activities, respectively. The results showed a 100% bacterial reduction against Staphylococcus aureus up to five washing cycles, and 100% before and 99% after one washing cycle against Escherichia coli. The antioxidant activity of functionalized viscose (70.5% and 60.1% for 60 min and 120 min pre-oxidized fabrics, respectively) decreased after washing, while the obtained color remained stable after five washing cycles. The results indicate that viscose fabric functionalized with pomegranate peel extract can be used in the production of bioactive clothing for individuals with sensitive skin, as well as household and healthcare textile products. Full article

Natural plant-based resources are rich in bioactive compounds that offer promising alternatives for developing sustainable, functional textiles. This study focuses on the extraction and application of natural dyes from Gardenia jasminoides as an eco-friendly substitute for conventional synthetic dyes. The dye was extracted using methanol–water (50:50) and ethanol–water (50:50) solvent systems, alongside conventional aqueous extraction, followed by characterization through column chromatography. The characterization of the extracted powders confirmed the presence of gardenia yellow pigments with strong coloration potential. Among the tested extraction methods, ultrasonic-assisted methanol–water extraction (M.W.U.) exhibited the highest dye yield of 29.5%, followed by ethanol–water ultra-sound extraction (E.W.U.) at 24.9%, water ultrasound extraction (W.U.) at 18.35%, and the lowest yield obtained from the water-heater method (W.H.) at 18.25%. The dyed cotton fabrics were tested for color strength (K/S), CIELAB, colorfastness (washing, light, rubbing), and functional properties (antibacterial and vector protection) according to standard operating procedures. The results revealed that an optimal mordant concentration produced the maximum color strength (K/S = 1.7730), with good rubbing (4–5), washing (4–5), and light fastness (5). The dyed fabrics also exhibited excellent antibacterial activity against both Staphylococcus aureus and Escherichia coli, as evaluated by the AATCC 100 test method. For instance, the vector protection property of the cotton dyed fabrics was also excellent, as confirmed by the cage test. Overall, the use of Gardenia jasminoides seed-based natural dye demonstrates not only desirable coloration and functional performance but also significant ecological advantages, reducing chemical pollution and supporting the transition toward environmentally sustainable textile processing. Full article

Antimicrobial resistance (AMR) is a major global health concern, which complicates treatment of microbial infections and wounds. Conventional therapies are no longer effective against drug resistant microbes; hence, novel antimicrobial approaches are urgently required. Silver nanoparticles (AgNPs) offer stronger antimicrobial activity, and in situ synthesis improves stability, uniformity, cost efficiency, and bioactivity while minimising contamination. These features make AgNPs well-suited for incorporation into textiles and wound dressings. Red wine extract (RW-E), rich in antioxidant and anti-inflammatory compounds was used to hydrothermally synthesise RW-AgNPs and RW-AgNPs-loaded on cotton (RWALC) by optimising pH and RW-E concentration. Characterisation was performed using UV–Vis spectroscopy, dynamic light scattering (DLS), and High Resolution and Scanning electron microscopy (HR-TEM and SEM). Antibacterial activities were evaluated against human pathogens through agar disc diffusion assay for RWALC and microdilution assay for RW-AgNPs. RWALC showed higher potency against both Gram-negative and Gram-positive bacteria, with inhibition zones of 12.33 ± 1.15 to 23.5 ± 5.15 mm, that surpassed those of ciprofloxacin (10 ± 3 to 19.17 ± 1.39 mm at 10 μg/mL). RW-AgNPs exhibited low minimum inhibitory concentrations (MIC: 0.195–3.125 μg/mL) and minimum bactericidal concentrations (MBC: 0.78–6.25 μg/mL). Preincubation with β-mercaptoethanol (β-ME) inhibited the antibacterial activity of RWALC, suggesting that thiolated molecules are involved in AgNPs-mediated effects. This study demonstrated that green-synthesised RW-AgNPs, incorporated in situ into cotton, conferred strong antibacterial properties, warranting further investigation into their mechanisms of action. Full article

In response to the growing demand for environmentally friendly and sustainable yet functional technical textiles, this research developed a spun-bonded nonwoven from the biodegradable thermoplastic starch-based biopolymer BIOPLAST^®, incorporating fruit extracts as natural sources of polyphenolic compounds and surface-active additives. Extracts from Vaccinium myrtillus L. and Sambucus nigra L. were applied onto a nonwoven’s surface via aerographic spraying using a water/ethanol system. The resulting materials were characterized in terms of morphology, physicochemical and mechanical behavior, surface characteristics, and stability under accelerated ageing and hydrolytic conditions. Treatment with the extracts increased the tensile strength by roughly 38% and elongation at break by about 50%, and it changed the surface from hydrophobic (contact angle of 115°) to hydrophilic, with contact angles of 83° for the blueberry-modified nonwoven and 55° for the elderberry-modified nonwoven. The modified nonwovens also showed sustained release of polyphenolic compounds over 72 h, which is beneficial for biomedical, healthcare, and cosmetic applications, where short-term use, controlled release of active compounds, and bioactivity are more important than long-term durability. Overall, the results indicate that BIOPLAST^®-based spun-bonded nonwovens can serve as fully bio-based carriers for fruit extracts in MedTech-related technical textiles, offering a straightforward way to introduce additional functionality into biodegradable nonwovens. Full article

Bombyx mori silk fibroin (BMSF) has developed from a textile fibre into a mature biomaterial with broad utility in regenerative medicine, owing to its unique hierarchical molecular structure. Its excellent biocompatibility, tuneable mechanical properties, optical property, and controllable biodegradability arise from its protein conformation, which can be precisely regulated through processing and fabrication strategies. Recent advances in bioengineering have further expanded the capabilities of BMSF, enabling the development of biomaterials with engineered architectures, tailored microtopographies, and enhanced bioactivity. These technological developments have facilitated the design of scaffolds that more effectively guide tissue regeneration and enhance functional outcomes. Such constructs have demonstrated promising outcomes in the regeneration of bone, cartilage, vascular, neural, corneal, and skin tissues. This review summarises current progress while emphasising emerging trends that couple BMSF’s unique molecular features with immune-responsive design, instructive microarchitectures that guide cell behaviour, composite scaffold design, and functionalisation with bioactive molecules. BMSF has been positioned as a structurally adaptable and biologically instructive platform whose continued progression will depend on integrating advanced fabrication, mechanistic understanding, and translational standardisation. Full article

Simulation studies of adsorption in complex effluents are challenging due to nonlinear interactions between sorbents, adsorbates and carrying flows. This study investigates effluents from oil and textile industries, characterised by their heavy metal content and chemical oxygen demand. It examines the process in a continuous-flow laboratory-scale adsorption system. Results were validated using process modelling based on mass and energy conservation, applied to an industrial adsorber. The model described surface sorption mechanisms on bioactivated carbon at the molecular level and predicted breakthrough curve profiles, integrated with Aspen Plus ^® adsorption simulation under industrially relevant conditions. Experimental data and model predictions showed good agreement, with relative deviations ranging from 0.2% to 24.6%. Differences in adsorption capacities between oily and textile effluents highlighted the influence of coexisting constituents. At the same time, the varied behaviour of identical components supported the hypothesis of multifactorial effects in complex mixtures. The optimisation study, using Response Surface Methodology with a Central Composite design, evaluated factors such as bed height, feed rate, and adsorption cycle time, achieving enhanced removal efficiencies of 62% for chemical oxygen demand and 25% for suspended solids. Full article

The purpose of this paper is to develop sustainable bio-colored healthcare cotton fabrics using chitosan/pectin layer-by-layer coatings enriched with strawberry pomace extract. Ultrasound-assisted extraction of bioactive compounds from strawberry pomace was optimized using a Box–Behnken experimental design to maximize the total polyphenol content (29.6 mg GAE/g DW). HPLC analysis confirmed the presence and quantity of anthocyanins in the extract obtained under optimized conditions (time: 37 min, ethanol concentration: 48.4%, liquid-to-solid ratio: 40.4 mL/g). This extract was used to enrich chitosan/pectin coatings, and applied onto cotton fabric using a layer-by-layer technique. Among the fabrics with 0, 4, 8, and 12 bilayers of chitosan/pectin coating enriched with extract, the 12-bilayer coated fabric exhibited the best bioactivity: 98.4% antioxidant activity, outstanding antibacterial efficacy, and the highest release of extract over 24 h. The last two properties showed a strong linear correlation with the number of bilayers, adsorbed extract, and weight gain. In vitro cytotoxicity testing proved the non-cytotoxic nature of 12-bilayer fabric extract. Additionally, the performed 12-bilayer coating imparted a natural reddish-brown color, high color strength (K/S = 1.45), and excellent UV protection (UPF 79.4), offering a sustainable, multifunctional approach for obtaining bio-colored cotton fabrics suited for wound dressing and other healthcare applications. Full article

Scientific research, within the framework of a circular and sustainable economy, has increasingly focused on wild plants and agricultural by-products as valuable sources of bioactive compounds for innovative applications. In this study, the plant species selected for extract preparation and evaluation of their dyeing properties included Isatis tinctoria L., Castanea sativa, Juglans regia L., Rumex crispus L., Arbutus unedo L., and Punica granatum L. Each extract was analyzed to assess its dyeing performance on cotton and other cellulosic fabrics. Cellulose pads dyed with peels of P. granatum extract (PPGE) proved to be versatile and effective, showing potential for use in extending the shelf life of various fruits such as strawberries, apples, cherries, and persimmons. The optimum dyeing condition for cellulose and cotton fabrics was found to be 6% w/v dye. These findings support the development of natural, multifunctional materials suitable for food packaging applications aimed at preserving fresh produce, as well as for sustainable textile dyeing. Full article

The growing concern over the environmental impacts caused by plant agriwaste has intensified the search for sustainable alternatives in manufacturing processes. This review explores the valorization of agro-industrial residues, such as those derived from banana, coconut, and pineapple, for example. It highlights their potential to be converted into value-added products, particularly within the textile sectors. Emphasis is given to the environmental and economic benefits of reusing biomass rich in fibers and bioactive compounds while discussing key technological, regulatory, and logistical barriers that still limit large-scale applications. In parallel, it presents recent advances in processing technologies, such as biocomposites and biochar, and the integration of circular economy principles to promote resource efficiency and waste reduction. The analysis also underscores the importance of public policies and financial incentives to drive innovation and ensure the viability of sustainable practices in industrial contexts. The article proposes an ideal circular production flow model that contrasts current linear practices with a regenerative, bio-based alternative. By mapping current challenges and future perspectives, this review expects to contribute to the debate on environmental responsibility, green technologies, and the economic potential of plant residue reuse in manufacturing chains. Full article

This interdisciplinary study explores the potential of bioactive compounds from Aronia melanocarpa pomace, a juice industry by-product. The ethanol extract of the pomace was analyzed using HPLC, revealing key polyphenolic acids and anthocyanins. The extract exhibited outstanding antioxidant activity (100% as measured by the ABTS assay and 98.23% as measured by the DPPH assay) and >99% antibacterial efficacy against E. coli and S. aureus. This bioactive extract was utilized in a one-step process to dye and functionalize textiles (wool, silk, cellulose acetate, cotton, and viscose), with cotton and viscose suited for colored disposable bioactive textiles, particularly protective healthcare textiles, due to strong antioxidant (>97% as measured by the ABTS assay and >76% as measured by the DPPH assay) and antibacterial (>75% for E. coli and >80% for S. aureus) properties. The aronia pomace extract was also incorporated into newly synthesized starch/gelatin hydrogels with a compression modulus of 0.041–0.127 MPa and equilibrium swelling ratios of 3.33–4.26 g/g. Functionalized hydrogels demonstrated over 99% ABTS antioxidant activity, while the antibacterial efficacy against E. coli and S. aureus exceeded 70% and 97%, respectively. These properties, combined with the hydrogels’ ability to control the release of extract compounds, make them adequate for wound care applications. The extract’s effectiveness as a green inhibitor for carbon steel, with inhibition efficiency surpassing 94% at a concentration of aronia pomace extract of 100 ppm, was confirmed by electrochemical methods. Moreover, the extract predominantly retards the cathodic reaction. The current research represents the first exploration of alternative and green sustainable technologies for developing novel products based on aronia pomace extract. Full article

Actinomycetes, especially Streptomyces, are prolific producers of bioactive metabolites, including pigments with potential applications in foods, textiles, cosmetics, and pharmaceuticals. Motivated by increasing concerns about the safety and environmental impact of synthetic pigments, this study aimed to optimize the production of an extracellular pigment-rich fraction from Streptomyces parvulus and to evaluate its bioactivities relevant for cosmeceuticals. A Plackett–Burman design was used to identify key variables influencing metabolite production, followed by optimization with a Box–Behnken design. The pigment-rich fraction was obtained after extraction with ethyl acetate from lyophilized supernatants and chemically characterized by IR and LC–MS. Biological assays were conducted to assess anti-tyrosinase, immunomodulatory, and antimicrobial activities. Temperature, incubation time, and agitation speed were identified as the most significant factors, with optimal conditions of 30 °C, 50 rpm, and 7 days yielding a pigment concentration of 465.3 μg/mL. LC–MS analysis revealed three 1,4-naphthoquinone-containing compounds, annotated as juglomycin Z (1), WS-5995B (2), and naphthopyranomycin (3), as the main constituents. The pigment-rich fraction showed modest anti-tyrosinase activity (10.9% at 300 μg/mL), immunomodulatory effects (TNF-α inhibition up to 36.9% and IL-10 stimulation up to 38.4% in macrophages), and antimicrobial activity against Staphylococcus epidermidis (15.8 mm inhibition halo, 91% growth reduction). The optimized fermentation model enhances pigment yield while reducing resource consumption, and the pigment-rich fraction exhibits multifunctional bioactivities, underscoring its potential as a natural cosmeceutical ingredient. Full article

Phoenix Dancong tea essential oil possesses unique aroma characteristics and bioactivities, offering broad application potential in the food, pharmaceutical, and daily chemical fields. To achieve efficient extraction and expand its use in functional textiles, supercritical CO₂ (SC-CO₂) extraction was employed to optimize the extraction process of Phoenix Dancong tea essential oil. Based on single-factor experiments, the optimal extraction conditions were determined as follows: pressure of 25 MPa, temperature of 50 °C, CO₂ flow rate of 8 L/h, and extraction time of 3 h, resulting in an essential oil yield of 1.12%. Response surface methodology (RSM) revealed that the experimental data fit the regression model well (R² = 95.49%, R²Adj = 89.69%). Furthermore, the extracted essential oil was blade-coating to cotton, nylon, polyester, and wool fabrics to evaluate its aroma retention performance. Results indicated that cotton fibers exhibited the best absorption and sustained fragrance retention, maintaining a high odor grade even after 8 weeks. This study provides a theoretical basis and practical reference for the green extraction of Phoenix Dancong tea essential oil and its application in smart aromatic textiles. Full article

Bamboo (subfamily Bambusoideae, Poaceae) ranks among the fastest-growing plants on Earth, achieving up to 1 m day⁻¹, significantly faster than other fast growing woody plant such as Eucalyptus (up to 0.6 m day⁻¹) and Populus (up to 0.5 m day⁻¹). Native to Asia, South America and Africa, and cultivated on approximately 37 million ha worldwide, bamboo delivers multifaceted environmental, social, and economic benefits. Historically central to construction, handicrafts, paper and cuisine, bamboo has evolved into a high-value cash crop and green innovation platform. Its rapid renewability allows multiple harvests of young shoots in fast-growing species such as Phyllostachys edulis and Dendrocalamus asper. Its high tensile strength, flexibility, and ecological adaptability make it suitable for applications in bioenergy (bioethanol, biogas, biochar), advanced materials (engineered composites, textiles, activated carbon), and biotechnology (fermentable sugars, prebiotics, biochemicals). Bamboo shoots and leaves provide essential nutrients, antioxidants and bioactive compounds with documented health and pharmaceutical potential. With a global market value exceeding USD 41 billion, bamboo demand continues to grow in response to the call for sustainable materials. Ecologically, bamboo sequesters up to 259 t C ha⁻¹, stabilizes soil, enhances agroforestry systems and enables phytoremediation of degraded lands. Nonetheless, challenges persist, including species- and age-dependent mechanical variability; vulnerability to decay and pests; flammability; lack of standardized harvesting and engineering codes; and environmental impacts of certain processing methods. This review traces bamboo’s trajectory from a traditional resource to a strategic bioresource aligned with Industry 5.0, underscores its role in low-emission, circular bioeconomies and identifies pathways for optimized cultivation, green processing technologies and integration into carbon-credit frameworks. By addressing these challenges through innovation and policy support, bamboo can underpin resilient, human-centric economies and drive sustainable development. Full article