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A Systematic Study of the Reactive In Situ Synthesis of Self-Assembled Silver Nanoparticles on Cotton Yarn
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Development of a Method to Evaluate the Dynamic Fit of Face Masks
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The Investigation of the Mechanical Behavior of a Braided Parachute Suspension Line Using a Mesomechanical Finite Element Model
Journal Description
Textiles
Textiles
is an international, peer-reviewed, open access journal on textile science and engineering published quarterly online by MDPI.
- Open Access— free for readers, with article processing charges (APC) paid by authors or their institutions.
- High Visibility: indexed within ESCI (Web of Science), Scopus, EBSCO and other databases.
- Journal Rank: JCR - Q1 (Materials Science, Textiles)
- Rapid Publication: manuscripts are peer-reviewed and a first decision is provided to authors approximately 28.2 days after submission; acceptance to publication is undertaken in 4.9 days (median values for papers published in this journal in the second half of 2024).
- Recognition of Reviewers: APC discount vouchers, optional signed peer review, and reviewer names published annually in the journal.
Impact Factor:
4.9 (2024);
5-Year Impact Factor:
5.1 (2024)
Latest Articles
From Waste to Value: Advances in Recycling Textile-Based PET Fabrics
Textiles 2025, 5(3), 24; https://doi.org/10.3390/textiles5030024 (registering DOI) - 28 Jun 2025
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The environmental burden of textile waste has become a critical challenge for sustainable development. This review explores recent developments in the recycling of textiles, especially polyethylene tereph-2 thalate (PET)-based fabrics, with a focus on fiber-to-fiber regeneration as a pathway toward circular textile production.
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The environmental burden of textile waste has become a critical challenge for sustainable development. This review explores recent developments in the recycling of textiles, especially polyethylene tereph-2 thalate (PET)-based fabrics, with a focus on fiber-to-fiber regeneration as a pathway toward circular textile production. Recent developments in PET recycling, such as mechanical and chemical recycling methods, are critically examined, highlighting the potential of chemical depolymerization for recovering high-purity monomers suitable for textile-grade PET synthesis. Special attention is given to electrospinning as an emerging technology for converting recycled PET into high-value nanofibers, offering functional properties suitable for advanced applications in filtration, medical textiles, and smart fabrics. The integration of these innovations, alongside improved sorting technologies and circular design strategies, is essential for overcoming current limitations and enabling scalable, high-quality recycling systems. This review aims to support the development of a more resource efficient textile industry by outlining key challenges, technologies, and future directions in PET recycling.
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Open AccessArticle
Analyzing the Effects of Sewing Compression on Thermal Efficiency in Baffled Jackets with an Advanced Walking Thermal Manikin
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Hassan Saeed, Adnan Ahmed Mazari and Md Tanzir Hasan
Textiles 2025, 5(2), 23; https://doi.org/10.3390/textiles5020023 - 16 Jun 2025
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Sewing is the major contributor to the manufacturing of protection wear for the survival of early human civilization against extreme weather conditions. Mechanized sewing witnessed developments during the middle of the 19th century, and tedious handwork was replaced by sewing machines. Despite the
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Sewing is the major contributor to the manufacturing of protection wear for the survival of early human civilization against extreme weather conditions. Mechanized sewing witnessed developments during the middle of the 19th century, and tedious handwork was replaced by sewing machines. Despite the modernization of sewing machine technologies, speed, material thicknesses, automation, and the introduction of AI in sewing, there is a longstanding problem of heat loss along stitch lines. The sewing material is compressed by the sewing thread, and this compression results in a bridge between the human body and the external cold environment. Garment technologists identify this problem and due to the lack of any technological solution, the problem is solved through complex material handling methods. A new sewing technological solution has been developed to solve this problem, called spacer stitching, which addresses the problem of compression along stitch lines. Two baffled jackets with sewn-through methods are prepared, one with the spacer stitching technology and the other with conventional sewing. Thermal resistance and insulation efficiency are evaluated using the Thermetrics thermal manikin “Sonny” under dynamic (walking) conditions to analyze the thermal resistance difference between the two types of sewing methods as well as the effects of motion on insulation. The results reveal that the jacket made with spacer stitching demonstrates significantly higher thermal resistance and enhanced wearer comfort compared to that produced using conventional methods. Additionally, variations in thermal resistance are observed across different zones of the thermal manikin. These findings highlight the potential of spacer stitching to improve thermal insulation and revolutionize high-performance outerwear design.
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Open AccessReview
Advances in Thermoregulating Textiles: Materials, Mechanisms, and Applications
by
Kuok Ho Daniel Tang
Textiles 2025, 5(2), 22; https://doi.org/10.3390/textiles5020022 - 11 Jun 2025
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Advancements in thermoregulating textiles have been propelled by innovations in nanotechnology, composite materials, and smart fiber engineering. This article reviews recent scholarly papers on experimental passive and active thermoregulating textiles to present the latest advancements in these fabrics, their mechanisms of thermoregulation, and
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Advancements in thermoregulating textiles have been propelled by innovations in nanotechnology, composite materials, and smart fiber engineering. This article reviews recent scholarly papers on experimental passive and active thermoregulating textiles to present the latest advancements in these fabrics, their mechanisms of thermoregulation, and their feasibility for use. The review underscores that phase-change materials enhanced with graphene, boron nitride, and carbon nanofibers offer superior thermal conductivity, phase stability, and flexibility, making them ideal for wearable applications. Shape-stabilized phase-change materials and aerogel-infused fibers have shown promising results in outdoor, industrial, and emergency settings due to their durability and high insulation efficiency. Radiative cooling textiles, engineered with hierarchical nanostructures and Janus wettability, demonstrate passive temperature regulation through selective solar reflection and infrared emission, achieving substantial cooling effects without external energy input. Thermo-responsive, shape-memory materials, and moisture-sensitive polymers enable dynamic insulation and actuation. Liquid-cooling garments and thermoelectric hybrids deliver precise temperature control but face challenges in portability and power consumption. While thermoregulating textiles show promise, the main challenges include achieving scalable manufacturing, ensuring material flexibility, and integrating multiple functions without sacrificing comfort. Future research should focus on hybrid systems combining passive and active mechanisms, user-centric wearability studies, and cost-effective fabrication methods. These innovations hold significant potential for applications in extreme environments, athletic wear, military uniforms, and smart clothing, contributing to energy efficiency, health, and comfort in a warming climate.
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Open AccessReview
Fashion to Dysfunction: The Role of Plastic Pollution in Interconnected Systems of the Environment and Human Health
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Adelaide Parks Lovett, Leslie Browning-Samoni and Charles Freeman
Textiles 2025, 5(2), 21; https://doi.org/10.3390/textiles5020021 - 10 Jun 2025
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The rapid production and disposal of synthetic textiles, driven by fast fashion and overconsumption, contribute significantly to environmental pollution and human health risks. Functional finishes often contain toxic substances that leach into aquatic systems. Laundering and abrasion release microplastic fibers (MPFs), commonly called
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The rapid production and disposal of synthetic textiles, driven by fast fashion and overconsumption, contribute significantly to environmental pollution and human health risks. Functional finishes often contain toxic substances that leach into aquatic systems. Laundering and abrasion release microplastic fibers (MPFs), commonly called microplastics, and anthropogenic microfibers (MFs) which degrade into nanoplastics (NPs) through mechanical stress, heat, and UV radiation. These particles bypass wastewater treatment and accumulate in human organs, including the liver, lungs, and brain. This review highlights the limitations of current waste management systems, the role of textile design in particle release, and the need for further research on airborne emissions and environmental interactions. Mitigating textile-derived plastic pollution will require biodegradable finishes, pre-consumer filtration systems, and circular consumption models supported by interdisciplinary collaboration.
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Open AccessArticle
Lyocell-Based Nonwovens: Mechanical Performance and Biodegradation Analysis
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Lúcia Rodrigues, João Medeiros, Rita Marques and Carla J. Silva
Textiles 2025, 5(2), 20; https://doi.org/10.3390/textiles5020020 - 4 Jun 2025
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The nonwoven industry is undergoing significant changes, driven by rapid growth and sustainability concerns, with a growing need to shift from fossil-based polymers like polyester (PES) and polypropylene (PP) fibres to biodegradable, fossil-free materials. Compared to other cellulose-based fibres, lyocell (LY) is a
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The nonwoven industry is undergoing significant changes, driven by rapid growth and sustainability concerns, with a growing need to shift from fossil-based polymers like polyester (PES) and polypropylene (PP) fibres to biodegradable, fossil-free materials. Compared to other cellulose-based fibres, lyocell (LY) is a promising solution due to its good mechanical performance and lower environmental impact. Additionally, cellulose acetate (CA) fibres, known for their thermoplastic and biodegradable properties, can act as a binder, offering another promising alternative to fossil-based fibres. This study explores the use of 100% LY fibres, alone and in blends with CA and recycled polyester (rPES) fibres, in the development of needle-punched nonwovens and assesses the mechanical benefits of adding a thermal bonding step. Among the blends, rPES-based nonwovens with thermal bonding showed the best results. 100% LY exhibited the best mechanical performance among needle-punched nonwovens, while rPES-based blends outperformed the others. Biodegradability and toxicity studies were also performed. 100% LY nonwovens fully biodegraded within 55 days, and 100% CA and 100% rPES showed no biodegradation. The findings revealed that the thermal process did not affect the disintegration level and, the germination of Brassica oleracea was not affected by soils in which the samples were buried for 75 days.
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Open AccessReview
Biotextiles for Biomedical Applications: A Review
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Heitor Luiz Ornaghi Júnior and Julia Pradella Garavatti
Textiles 2025, 5(2), 19; https://doi.org/10.3390/textiles5020019 - 12 May 2025
Abstract
The demand for healthcare and medical devices increases as the population ages. With the advance of textile science and technology, new products have been developed to replace the traditional ones, including biotextiles. This review has the objective of presenting biotextiles for biomedical applications,
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The demand for healthcare and medical devices increases as the population ages. With the advance of textile science and technology, new products have been developed to replace the traditional ones, including biotextiles. This review has the objective of presenting biotextiles for biomedical applications, specifically drug delivery systems, medical implants, and regenerative medicine, showing the scientific progress in the respective fields, some relevant scientific studies, and commercially available products. The aim is to present to readers a quick overview guide for reference, including future trends and challenges.
Full article
(This article belongs to the Special Issue Advances of Medical Textiles: 2nd Edition)
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Analysis of the Drapeability and Bending Rigidity of Clothing Packages—A Preliminary Study
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Michał Stępień and Iwona Frydrych
Textiles 2025, 5(2), 18; https://doi.org/10.3390/textiles5020018 - 9 May 2025
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This paper concerns the study of the multidirectional drape and bending rigidity of clothing packages combined with three types of adhesive inserts. The aim of this research was to investigate the effect of introducing seams of differentiated complexity to clothing packages consisting of
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This paper concerns the study of the multidirectional drape and bending rigidity of clothing packages combined with three types of adhesive inserts. The aim of this research was to investigate the effect of introducing seams of differentiated complexity to clothing packages consisting of cotton fabric and adhesive inserts. The adhesive inserts were differentiated according to their mass per square meter. Three kinds of seams differing by the number of bent and sewn layers were introduced into packages, and two techniques of bonding, differentiated by the sequence of operations, were applied. The results of the influence of bonding technique on the bending rigidity and multidirectional drape for packages with seams and those without them are discussed. All of the tests carried out were aimed at answering the question of how seam introduction and its complexity (the number of sewn layers) influence the bending rigidity and drapeability of clothing packages in order to facilitate clothing technologists in the proper selection of appropriate adhesive inserts for the engineered design of clothing products.
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Open AccessReview
Rubber-Based Sustainable Textiles and Potential Industrial Applications
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Bapan Adak, Upashana Chatterjee and Mangala Joshi
Textiles 2025, 5(2), 17; https://doi.org/10.3390/textiles5020017 - 8 May 2025
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This review explores the evolving landscape of sustainable textile manufacturing, with a focus on rubber-based materials for various industrial applications. The textile and rubber industries are shifting towards eco-friendly practices, driven by environmental concerns and the need to reduce carbon footprints. The integration
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This review explores the evolving landscape of sustainable textile manufacturing, with a focus on rubber-based materials for various industrial applications. The textile and rubber industries are shifting towards eco-friendly practices, driven by environmental concerns and the need to reduce carbon footprints. The integration of sustainable textiles in rubber-based products, such as tires, conveyor belts, and defense products, is becoming increasingly prominent. This review discusses the adoption of natural fibers like flax, jute, and hemp, which offer biodegradability and improved mechanical properties. Additionally, it highlights sustainable elastomer sources, including natural rubber from Hevea brasiliensis and alternative plants like Guayule and Russian dandelion, as well as bio-based synthetic rubbers derived from terpenes and biomass. The review also covers sustainable additives, such as silica fillers, nanoclay, and bio-based plasticizers, which enhance performance while reducing environmental impact. Textile–rubber composites offer a cost-effective alternative to traditional fiber-reinforced polymers when high flexibility and impact resistance are needed. Rubber matrices enhance fatigue life under cyclic loading, and sustainable textiles like jute can reduce environmental impact. The manufacturing process involves rubber preparation, composite assembly, consolidation/curing, and post-processing, with precise control over temperature and pressure during curing being critical. These composites are versatile and robust, finding applications in tires, conveyor belts, insulation, and more. The review also highlights the advantages of textile–rubber composites, innovative recycling and upcycling initiatives, addressing current challenges and outlining future perspectives for achieving a circular economy in the textile and rubber sectors.
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Open AccessReview
From Fabric to Finish: The Cytotoxic Impact of Textile Chemicals on Humans Health
by
Vera Machado, Andréa Marinho, Paula Vieira de Castro and Teresa Silva
Textiles 2025, 5(2), 16; https://doi.org/10.3390/textiles5020016 - 7 May 2025
Cited by 1
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Humans are in constant contact with clothing and textiles throughout their lives, which can expose them to chemicals present in these materials. Chemicals used in fiber production and in material processing can be absorbed through the skin, ingested, or inhaled, causing allergic reactions.
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Humans are in constant contact with clothing and textiles throughout their lives, which can expose them to chemicals present in these materials. Chemicals used in fiber production and in material processing can be absorbed through the skin, ingested, or inhaled, causing allergic reactions. Advancements in modern textiles have made them more versatile and functional for a variety of applications, resulting in the use of more chemicals. Regarding the textile industry, several studies have focused on the environmental impact of its effluents and dyes, and, more recently, several studies have focused on textile waste impact in general. Nevertheless, few studies have been carried out on human cytotoxicity, and very little is known about the dangers of long-term use of textiles. The aim of this work was to review the literature to understand what has been done in the field of textile cytotoxicity. In addition, this work also highlights the existing gap regarding regulation and standardized tests for the analysis of everyday clothing. There is an urgent need to establish regulations and standardize testing protocols to assess the potential cytotoxic effects that may arise from finished textile products before they are marketed, in order to guarantee consumer safety.
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Open AccessArticle
Optimization of Lubrication Amount for Sewing Threads
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Adnan Mazari and Funda Buyuk Mazari
Textiles 2025, 5(2), 15; https://doi.org/10.3390/textiles5020015 - 28 Apr 2025
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Sewing needle heating is a common problem for the sewing of technical and medical textiles. The hot needle causes burnt spots on fabric, breakage of the thread, and weak seam strength. Multiple ways are used in industry to cool the needle including compressed
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Sewing needle heating is a common problem for the sewing of technical and medical textiles. The hot needle causes burnt spots on fabric, breakage of the thread, and weak seam strength. Multiple ways are used in industry to cool the needle including compressed air, thread lubrication, and needle coatings. The most economical way of reducing needle heat is to use thread lubrication. This technique needs a lot of research because the bucket of lubrication installed on the sewing machine provides irregular amounts of the micro layer on the thread and there is no research showing how much should be used. In this research, different amounts of pre-lubricated threads are used to measure their impact on coefficient of friction, tensile strength, needle temperature, and overall performance of the seam depending on lubrication amount. The research work is focused on the disadvantages of irregular lubrication and finding optimized lubricant amount for better sewing performance with low needle temperature.
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Open AccessArticle
Sustainable Fabrication of Reddish Silk Fabric with Enhanced Color Intensity and Fastness Using Lycopene
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Jiahong Zuo and Yuyang Zhou
Textiles 2025, 5(2), 14; https://doi.org/10.3390/textiles5020014 - 15 Apr 2025
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A significant development has been the integration of natural elements with bio-based materials to produce entirely bio-based functional textiles. In this investigation, lycopene, derived from tomatoes, is used as a new natural red dye for silk. A suitable solvent was selected to precisely
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A significant development has been the integration of natural elements with bio-based materials to produce entirely bio-based functional textiles. In this investigation, lycopene, derived from tomatoes, is used as a new natural red dye for silk. A suitable solvent was selected to precisely measure the lycopene content in silk. The stability of lycopene in a simulated dye bath was examined in relation to heating duration and pH values. Central composite design was employed to evaluate the impact of dyeing conditions on the color intensity of silk. The results showed that lycopene dissolves more efficiently in dichloromethane than in water or ethanol. UV–Vis absorption spectra, which remained nearly constant, indicate that lycopene retains its stability after being heated at 90 °C for 60 min or when the pH is between 3.2 and 6.2. Higher temperatures lead to increased lycopene adsorption, thereby enhancing color intensity. Based on the ANOVA analysis from the central composite design experiment, the most influential factor affecting color intensity is the concentration of lycopene, followed by temperature, and then pH. As the lycopene concentration increases, the color intensity and saturation of the dyed silk also increase. Although the lycopene-dyed silk shows good wash fastness, there is room for improvement in rub fastness. In summary, this study confirms the potential of using lycopene as a new natural red dye for silk.
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Open AccessArticle
Ultralong Carbon Nanotube Yarns Integrated as Electronic Functional Elements in Smart Textiles
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Ayelet Karmon, Ori Topaz, Raman Tandon, Andy Weck, Ortal Tiurin, Sheizaf Rafaeli and Zeev Weissman
Textiles 2025, 5(2), 13; https://doi.org/10.3390/textiles5020013 - 4 Apr 2025
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Smart textiles are an evolving field, but challenges in durability, washing, interfacing, and sustainability persist. Widespread adoption requires robust, lightweight, fully integrated fiber-based conductors. This paper proposes using ultralong carbon nanotube (UCNT) yarns with a width-to-length ratio of several orders of magnitude larger
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Smart textiles are an evolving field, but challenges in durability, washing, interfacing, and sustainability persist. Widespread adoption requires robust, lightweight, fully integrated fiber-based conductors. This paper proposes using ultralong carbon nanotube (UCNT) yarns with a width-to-length ratio of several orders of magnitude larger than typical carbon nanotube fibers. These yarns enable the manufacturing of stable, workable structures, composed of a network of twisted fibers (tows), which are suitable for fabric integration. Our research includes the creation of textile prototype demonstrators integrated with coated and non-coated UCNT yarns, tested under military-grade standards for both mechanical durability and electric functionality. The demonstrators were evaluated for their electrical and mechanical properties under washability, abrasion, and weathering. Notably, polymer-coated UCNT yarns demonstrated improved mechanical durability and electrical performance, showing promising results. However, washing tests revealed the presence of UCNT nanofibers in the residue, raising concerns due to their classification as hazards by the World Health Organization. This paper examines the sources of fiber release and discusses necessary improvements to coating formulations and testing protocols to mitigate fiber loss and enhance their practical viability. These findings underscore both the potential and limitations of UCNT yarns in military textile applications.
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Open AccessReview
Artificial Intelligence Driving Innovation in Textile Defect Detection
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Ahmet Ozek, Mine Seckin, Pinar Demircioglu and Ismail Bogrekci
Textiles 2025, 5(2), 12; https://doi.org/10.3390/textiles5020012 - 4 Apr 2025
Cited by 2
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The cornerstone of textile manufacturing lies in quality control, with the early detection of defects being crucial to ensuring product quality and sustaining a competitive edge. Traditional inspection methods, which predominantly depend on manual processes, are limited by human error and scalability challenges.
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The cornerstone of textile manufacturing lies in quality control, with the early detection of defects being crucial to ensuring product quality and sustaining a competitive edge. Traditional inspection methods, which predominantly depend on manual processes, are limited by human error and scalability challenges. Recent advancements in artificial intelligence (AI)—encompassing computer vision, image processing, and machine learning—have transformed defect detection, delivering improved accuracy, speed, and reliability. This article critically examines the evolution of defect detection methods in the textile industry, transitioning from traditional manual inspections to AI-driven automated systems. It delves into the types of defects occurring at various production stages, assesses the strengths and weaknesses of conventional and automated approaches, and underscores the pivotal role of deep learning models, especially Convolutional Neural Networks (CNNs), in achieving high precision in defect identification. Additionally, the integration of cutting-edge technologies, such as high-resolution cameras and real-time monitoring systems, into quality control processes is explored, highlighting their contributions to sustainability and cost-effectiveness. By addressing the challenges and opportunities these advancements present, this study serves as a comprehensive resource for researchers and industry professionals seeking to harness AI in optimizing textile production and quality assurance amidst the ongoing digital transformation.
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Open AccessArticle
Dyeing Performance of a Synthesized and Ultrafiltrated Bifunctional Reactive Dye with Two Vinylsulfone Groups on Cotton Fabrics
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Smaro S. Lykidou, Vasileios Daniilidis, Evangelia C. Vouvoudi and Nikolaos F. Nikolaidis
Textiles 2025, 5(2), 11; https://doi.org/10.3390/textiles5020011 - 28 Mar 2025
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The objective of this study is to investigate the performance of the ultrafiltration process as a purification method on the dyeing properties of a newly synthesized homobifunctional reactive dye. This is a green–blue reactive dye with two vinylsulfone groups. Namely, several properties, such
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The objective of this study is to investigate the performance of the ultrafiltration process as a purification method on the dyeing properties of a newly synthesized homobifunctional reactive dye. This is a green–blue reactive dye with two vinylsulfone groups. Namely, several properties, such as exhaustion, substantivity, fixation, time to half dyeing, migration index, light fastness, and the effect of metal salts, were studied thoroughly. It was proven that the processed bifunctional reactive dye shows higher exhaustion, substantivity, and dye-uptake values than the untreated one. It was found that the dye fixation is higher for the ultrafiltrated (92%) compared to the non-ultrafiltrated (85%) dye, while the migration index is slightly lower. It is indicated that, due to the possible chemical affinity between the dye and the substrate, a stronger retention is noticed for the treated dye. All in all, high fixation and substantivity lead to higher dye valorization and result in less hydrolyzed waste dyestuff, leading to less water and organic liquid waste at an industrial scale. The effect of metal salts addition (Fe3+, Co2+ and Cu2+) was studied as well, for comparison reasons, but it was found to be unnecessary. It is proven by the property values calculated that the overall process is valuable, since lower dyebath concentrations are required for satisfactory results. Thus, in large-scale dyeings, the ultrafiltration process can be proven to be valuable for environmental protection reasons.
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Open AccessArticle
The Investigation of the Mechanical Behavior of a Braided Parachute Suspension Line Using a Mesomechanical Finite Element Model
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Catherine P. Barry, Keith Bergeron, Scott E. Stapleton, David J. Willis, Gregory Noetscher, Christine Charrette and James A. Sherwood
Textiles 2025, 5(2), 10; https://doi.org/10.3390/textiles5020010 - 26 Mar 2025
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Parachute suspension lines shed vortices during descent, and these vortices develop oscillating aerodynamic forces that can induce forced parasitic vibrations of the lines, which can have an adverse impact on the parachute system. Understanding the line’s mechanical behavior can assist in studying the
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Parachute suspension lines shed vortices during descent, and these vortices develop oscillating aerodynamic forces that can induce forced parasitic vibrations of the lines, which can have an adverse impact on the parachute system. Understanding the line’s mechanical behavior can assist in studying the vibrations experienced by the suspension lines. A well-calibrated structural model of the suspension line could be used to help to identify how the braid’s architecture contributes to its mechanical behavior and to explore if and how a suspension line can be designed to mitigate these parasitic vibrations. In the current study, a mesomechanical finite element model of a polyester braided parachute suspension line was constructed. The line geometry was built in the Virtual Textile Morphology Suite (VTMS), and a user material model (UMAT) was implemented in LS-DYNA® release 14 to describe the material behavior of the individual tows. The material properties were initially calibrated using experimental tension tests on individual tows, which exhibited an initial modulus of ~4100 MPa before transitioning to ~3200 MPa at a stress of 30 MPa. When these properties were applied to the full braid model, slight adjustments were made to account for geometric complexities in the braid structure, improving the correlation between the model and experimental tensile tests. The final calibrated model captured the bilinear tensile behavior of the braid, with an initial modulus of 2219 MPa and a secondary modulus of 1350 MPa, compared to experimental values of 2253 MPa and 1420 MPa, respectively, showing 2% and 5% differences. The calibrated model of the braided cord was then subjected to torsion, and the results showed good agreement with dynamic and static experimental torsion tests, with a difference of 8–19% for dynamic tests and 13–27% for static tests when compared to experimental values. The availability of virtual models of suspension lines can ultimately assist in the design of suspension lines that mitigate flow-induced vibration.
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Open AccessArticle
Development of a Method to Evaluate the Dynamic Fit of Face Masks
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Katarina E. Goodge, Drew E. Brown, Margaret Frey and Fatma Baytar
Textiles 2025, 5(1), 9; https://doi.org/10.3390/textiles5010009 - 24 Feb 2025
Abstract
Evaluating designed objects in real-world use cases enables usability optimization. For functional objects such as face masks, the mask must fit the user initially and continue to fit during movements such as talking. This paper describes methodology development for dynamic fit analysis of
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Evaluating designed objects in real-world use cases enables usability optimization. For functional objects such as face masks, the mask must fit the user initially and continue to fit during movements such as talking. This paper describes methodology development for dynamic fit analysis of face masks using 3D head scans. Participants were scanned while wearing Basic, Cup, and Petal model masks before and after reading a passage aloud and completed surveys across eight fit dimensions. Face and mask measurements were virtually extracted from the head scans for quantitative fit analysis, and mask overlays were inspected for qualitative fit analysis. Four of eleven facial measurements changed significantly from closed to open-mouth posture while the nasal dorsum was identified as a stable landmark and served as a reference to define a mask shift metric. The mask shift was compared to the survey results for the model masks, with the Cup design fitting best and the Petal design rated as most comfortable. Poor fit modes identified from mask overlays were fabric buckling, compressed nose and ears, and gapping between the mask and facial features. This methodology can be implemented during the analysis stage of the iterative design process and complements static fit analyses.
Full article
(This article belongs to the Special Issue Reinventing Textiles: The Intersection of Biology, Technology, and Design)
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Open AccessReview
The Shroud of Turin: An Overview of the Archaeological Scientific Studies
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Ioannis Karapanagiotis
Textiles 2025, 5(1), 8; https://doi.org/10.3390/textiles5010008 - 19 Feb 2025
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The Shroud of Turin attracts consistently the interest of both the scientific community and the general public, as many believe that it is the burial cloth of Christ. This article aims to provide a comprehensive review of the relevant scientific research addressing two
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The Shroud of Turin attracts consistently the interest of both the scientific community and the general public, as many believe that it is the burial cloth of Christ. This article aims to provide a comprehensive review of the relevant scientific research addressing two key questions: (i) how were the image of the human body and the bloodstains formed on the Shroud? (ii) What is the age of the Shroud? The answer to the first question remains a mystery, and the article explores the most promising hypotheses. Consequently, the scientific community should have another opportunity in the near future, similar to that of the 1978 STURP campaign, to study the object. The 1989 radiocarbon dating of the Shroud, which addressed the second question and suggested that the linen cloth dates to the 14th century AD, is discussed in light of hypotheses and experimental studies that have raised concerns and objections about the Shroud’s possible medieval origin. It is concluded that the evidence from the significant reports published to date, which challenge the radiocarbon dating, is insufficient to overturn its finding. However, extracting new samples from different parts of the object to perform a second series of radiocarbon dating measurements is suggested.
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Open AccessArticle
A Systematic Study of the Reactive In Situ Synthesis of Self-Assembled Silver Nanoparticles on Cotton Yarn
by
Hamed Mohammadi Mofarah, Mutalifu Abulikemu, Hyung Woo Choi and Ghassan E. Jabbour
Textiles 2025, 5(1), 7; https://doi.org/10.3390/textiles5010007 - 13 Feb 2025
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Silver nanoparticles (AgNPs) have attracted considerable interest for various applications, including antiviral and antimicrobial treatments, textile nanocomposites, heat transfer and strain sensing textiles, flexible electronics, and smart textiles. Their unique properties, determined by their size, shape, and morphology, render them suitable for a
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Silver nanoparticles (AgNPs) have attracted considerable interest for various applications, including antiviral and antimicrobial treatments, textile nanocomposites, heat transfer and strain sensing textiles, flexible electronics, and smart textiles. Their unique properties, determined by their size, shape, and morphology, render them suitable for a wide range of uses, such as antimicrobial treatments, anticancer therapy, drug delivery, personal protective equipment (PPE), and catalysis. In this investigation, we present an in situ reactive technique for the self-assembly of AgNPs directly onto cotton yarn. A systematic investigation was undertaken to establish the influence of several synthesis parameters on the average size of AgNPs. The variables under consideration included the ambient vacuum conditions, the concentration of both Ag precursor and reducing agent, the growth temperature, and the duration of thermal treatment. By precisely optimizing these parameters, we successfully regulated the AgNPs size range between 10 and 50 nm on the cotton yarn. The findings of this study elucidate the methodology of the controlled synthesis of AgNPs on cotton yarn for potential advancements in smart textile technologies.
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Open AccessArticle
Research on the Construction of Cu2O Photonic Crystals on Different Textile Substrates and Their Mechanical Properties
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Chunxing Zhou, Zhen Yin, Yiqin Shao, Guocheng Zhu, Parpiev Khabibulla, Adkhamjon Gafurov and Juramirza Abdiramatovich Kayumov
Textiles 2025, 5(1), 6; https://doi.org/10.3390/textiles5010006 - 13 Feb 2025
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Structural color-generating materials are expected to replace pigments and dyes as a new type of color-developing materials with good light stability and bright colors. Due to the relatively high refractive index of Cu2O microspheres, they have strong Mie scattering in the
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Structural color-generating materials are expected to replace pigments and dyes as a new type of color-developing materials with good light stability and bright colors. Due to the relatively high refractive index of Cu2O microspheres, they have strong Mie scattering in the visible region. Herein, various sizes of Cu2O microspheres were synthesized by a two-step reduction method, and the Cu2O spheres were firmly bonded to the fabrics by using the PVA binder. Four different fabrics (cotton, silk, polyester, and nylon fabrics) were evaluated to investigate the physical properties and color fastness. It turns out that the tensile and tearing properties of the Cu2O structured fabrics decreased to a certain extent, and the bursting properties of fabrics increased, except for the cotton structured fabrics. Meanwhile, all the structural colored fabrics showed excellent color fastness to shearing, rubbing, and washing. This study provides experimental data for developing the application of structural colors on different fabrics.
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Open AccessArticle
Development of Thermally Insulating Nonwovens from Milkweed Fibers Using an Air-Laid Spike Process
by
Deborah Lupescu, Mathieu Robert, Simon Sanchez-Diaz and Said Elkoun
Textiles 2025, 5(1), 5; https://doi.org/10.3390/textiles5010005 - 22 Jan 2025
Abstract
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Milkweed (MW) fiber is a natural fiber that provides tremendous thermal insulation properties due to its lightweight hollow structure. This study aimed to investigate the effect of milkweed fiber as a thermal fiber in nonwovens. Milkweed fibers were blended with a low-melt fiber
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Milkweed (MW) fiber is a natural fiber that provides tremendous thermal insulation properties due to its lightweight hollow structure. This study aimed to investigate the effect of milkweed fiber as a thermal fiber in nonwovens. Milkweed fibers were blended with a low-melt fiber consisting of a polyethylene terephthalate core, a polyolefin sheath (LM 2.2), and polylactic acid (PLA) fiber. Nonwovens with different fiber contents were manufactured using an air-laid Spike process to determine their effect on thermal and mechanical properties. Then, the nonwovens were compared with Thinsulate® and Primaloft®, two commercially synthetic insulation products. Structural properties, including mass per unit area, thickness, and porosity and thermal properties were studied. Furthermore, compression and short-term compression recovery were also evaluated. The results revealed that milkweed-based nonwovens that contained 50 wt% or 70 wt% of milkweed presented a lower thermal conductivity than synthetic nonwovens. Milkweed nonwovens of the same thickness provided identical thermal resistance as Thinsulate® and Primaloft. Sample 3, composed of 50 wt% MW, 20 wt% LM 2.2, and 30 wt% PLA, demonstrated the same thermal insulation as Thinsulate® with a weight three times lighter. Milkweed nonwovens presented higher moisture regain values than Thinsulate® and Primaloft®, without affecting thermal conductivity.
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