Role of knitted techniques in recent developments of biomedical applications: A review

Ahmed, Usman; Hussain, Tanveer; Abid, Sharjeel

doi:10.1177/15589250231180293

Cited by 4 publications

(2 citation statements)

References 87 publications

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“…All types of knitted fabrics stem from these foundational structures, which are: single-knit, rib, and interlock [2]. Woven and knit fabrics serve versatile functions across a wide range of industries, including fashion [3], biomedical [4], automotive [5], civil engineering [6,7], and filtration [8].…”

Section: Introductionmentioning

confidence: 99%

Fibrous Structures: An Overview of Their Responsiveness to External Stimuli towards Intended Application

Ferreira,

Gonçalves,

Antunes

et al. 2024

Polymers

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In recent decades, the interest in responsive fibrous structures has surged, propelling them into diverse applications: from wearable textiles that adapt to their surroundings, to filtration membranes dynamically altering selectivity, these structures showcase remarkable versatility. Various stimuli, including temperature, light, pH, electricity, and chemical compounds, can serve as triggers to unleash physical or chemical changes in response. Processing methodologies such as weaving or knitting using responsive yarns, electrospinning, as well as coating procedures, enable the integration of responsive materials into fibrous structures. They can respond to these stimuli, and comprise shape memory materials, temperature-responsive polymers, chromic materials, phase change materials, photothermal materials, among others. The resulting effects can manifest in a variety of ways, from pore adjustments and altered permeability to shape changing, color changing, and thermal regulation. This review aims to explore the realm of fibrous structures, delving into their responsiveness to external stimuli, with a focus on temperature, light, and pH.

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Section: Introductionmentioning

confidence: 99%

Fibrous Structures: An Overview of Their Responsiveness to External Stimuli towards Intended Application

Ferreira,

Gonçalves,

Antunes

et al. 2024

Polymers

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“…However, based on the current overall technological maturity and practical applicability in application areas, along with a comprehensive comparison of several existing technologies, it can be concluded that fiber filtration technology is one of the most widely used technologies at present, among which, air filters are widely used due to their ability to filter and purify particulate matter in the air [ 15 ]. The most commonly used air filtration materials in the current market are mainly melt-blown ultrafine-fiber non-woven fabrics [ 16 ], but the scale of melt-blown fibers is mostly above micrometers, meaning that they cannot effectively intercept tiny, deadly particles in the air. Therefore, the preparation and optimization of fiber materials have always been among the main directions in research on high-performance filtration materials [ 17 ].…”

Section: Introductionmentioning

confidence: 99%

The Performance Testing and Analysis of Common New Filter Materials: A Case of Four Filter Materials

Sun,

Zhang,

Xue

et al. 2024

Materials

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The complex air environment makes it urgent to build good and safe indoor environments, and the study and application of new materials have become the focus of current research. In this study, we tested and analyzed the structural parameters and filtration performances of the four most commonly used new filter materials in the current market. The results showed that all four new filter materials showed a trend of first increasing and then decreasing their filtration efficiency with an increase in filtration velocity. The filtration efficiency of the materials was as follows: PTFE > glass fiber > nanomaterial > electret. The filtration efficiency of all materials reached its maximum when the filtration velocity was 0.2 m/s. The filtration efficiency of the PTFE for PM10, PM2.5, and PM1.0 was higher than that of the other three materials, with values of 0.87% to 24.93%, 1.21% to 18.69%, and 0.56% to 16.03%, respectively. PTFE was more effective in capturing particles smaller than 1.0 μm. Within the testing velocity range, the resistance of the filter materials was as follows: glass fiber > PTFE > electret > nanomaterial, and the resistance of the four materials showed a good fitting effect. It is also necessary to match the resistance with the filtration efficiency during use, as well as to study the effectiveness of filter materials in blocking microorganisms and absorbing toxic gases. Overall, PTFE showed the best comprehensive performance, as well as providing data support for the selection of related materials or the synthesis and research of filter materials in the future.

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Empowering Imagination in Design Practice: Focus on Knitwear Design

Lo Scocco

2024

Springer Series in Design and Innovation

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Role of knitted techniques in recent developments of biomedical applications: A review

Cited by 4 publications

References 87 publications

Fibrous Structures: An Overview of Their Responsiveness to External Stimuli towards Intended Application

Fibrous Structures: An Overview of Their Responsiveness to External Stimuli towards Intended Application

The Performance Testing and Analysis of Common New Filter Materials: A Case of Four Filter Materials

Empowering Imagination in Design Practice: Focus on Knitwear Design

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