ライフサイエンスコーパス: textile

1 birth to self-powered electronic textiles (e-textiles).

2 he valve opens and the liquid penetrates the textile.

3 e liquid cannot pass through the hydrophobic textile.

4 ner by fabricating an all-solid photovoltaic textile.

5 the impacts associated with nanoenabling the textile.

6 defined lines in the manner of a macroscopic textile.

7 ve energy harvesters in wearable devices and textiles.

8 he so-called electronic skins and electronic textiles.

9 strategy for the production of Zr-MOF-coated textiles.

10 the context of total fluorine for papers and textiles.

11 that operate based on electrowetting through textiles.

12 orine remains associated with the papers and textiles.

13 t of the methods used to produce macroscopic textiles.

14 l stimuli, are essential components of smart textiles.

15 hahrbanu site in Iran unearthed several silk textiles.

16 ld integrated electronic devices directly in textiles.

17 h energy density that can be integrated into textiles.

18 fibres are essential to the development of e-textiles.

19 building insulation foams, electronics, and textiles.

20 r is required to control bacterial growth in textiles.

21 ase more particulate Ag than conventional Ag textiles.

22 ciation and release upon use of nanoenhanced textiles.

23 ble textiles and for six laboratory-prepared textiles.

24 ctures, as well as the efforts toward 3DP of textiles.

25 m composites in comparison to surface-coated textiles.

26 sensitive flexible materials like papers and textiles.

27 a-long fibers for the production of superior textiles.

28 , knotted, or woven into flexible electronic textiles.

29 le devices for wearable electronics or smart textiles.

30 hly conductive and cost-effective electronic textiles.

31 Detection limits for aromatic amines in textiles (0.007-2 mg kg(-1)) were well below the limits

32 There is good reason to consider synthetic textiles a major source of microplastic fibers, and it w

33 Next, we systematically review smart textiles according to their abilities to harvest biomech

34 ores, the nanoporous metallized polyethylene textile achieves a minimal IR emissivity (10.1%) on the

35 textile is likely to continue leaching from textiles after disposal in a landfill.

36 's fluff, an ultrasensitive and flexible all-textile airflow sensor based on fabric with in situ grow

37 It is believed that the ultrasensitive all-textile airflow sensor holds great promise for applicati

38 cellulose has been successfully exploited in textile and detergent industries.

39 ds is ideal for the next generation of smart textile and intelligent clothing.

40 duction and their application, mainly in the textile and leather industry, making the dyestuff indust

41 inst mechanical deformations associated with textile and skin-based on-body sensing operations.

42 ial (in the range of 100-1000 V) between the textile and the liquid, the valve opens and the liquid p

43 nstrate artificial muscle sewing threads and textiles and coiled structures that exhibit nearly unlim

44 y via trials using microfibers shed from new textiles and environmental samples.

45 re conducted for four commercially available textiles and for six laboratory-prepared textiles.

46 lly, we provide a critical analysis of smart textiles and insights into remaining challenges and futu

47 ions were found between FR levels in treated textiles and measures of dermal and inhalation exposure.

48 olds great promise for applications in smart textiles and wearable electronics.

49 will not only deepen the ties between smart textiles and wearable NGs, but also push forward further

50 e supercapacitor (SC) for self-powered smart textiles and wearable systems is presented.

51 century written records as well as ceramic, textile, and isotopic data.

52 the human experience, such as skin, tissue, textiles, and clothing.

53 enewable fuels, fine chemicals, food, feeds, textiles, and paper products.

54 tics into soils, and postconsumer processes, textiles, and personal care products release most of the

55 including membranes, semiconductors, metals, textiles, and polymers, because of a combination of inte

56 h as cloth communication devices, electronic textiles, and robotic sensory skin.

57 The cell with the 3D textile anode framework, Gd:CeO2 -Li/Na2 CO3 composite e

58 ive graphene-Ag composite ink for wearable e-textiles applications.

59 Textiles are among the longest and most widespread techn

60 Textiles are one of the major sources of microplastic po

61 tion and characterization of highly flexible textiles are reported.

62 Textiles are their own class of materials due to the spe

63 kjet-printed wearable electronic textiles (e-textiles) are considered to be very promising due to exc

64 significant for understanding the history of textiles, as well as production and human adaptation in

65 can be found in many areas, including smart textiles, autonomous robotics, biomedical devices, drug

66 ng to be woven into a commercial textile for textile based sensors, which can detect magnitude as wel

67 Here, a novel textile-based air cathode is developed with a triple-pha

68 Here, we discuss the latest advances in textile-based and skin-like wearable sensors with a focu

69 construct a sensor-integrated, lightweight, textile-based arm sleeve that can recognize gestures wit

70 Flexible epidermal tattoo and textile-based electrochemical biosensors have been devel

71 Due to noncompetitive transport, the textile-based Li-O2 cathode exhibits a high discharge ca

72 l textile processes fosters the emergence of textile-based nanogenerators (NGs), which will inevitabl

73 ully integrated wearable wireless tattoo and textile-based nerve-agent vapor biosensor systems offer

74 Here, large-area all-textile-based pressure-sensor arrays are successfully re

75 The textile-based structure can be applied to a range of app

76 de a new design concept for high-performance textile-based TENGs and expand their application scope i

77 terials, smart systems, photonics, robotics, textiles, Big Data and ICT (information & communication

78 ctrically conductive, insulated, hydrophobic textiles, but the concept can be extended to other porou

79 egration of PV devices onto high temperature textiles, but to widen the range of applications future

80 about inks from 15(th) century BCE Egyptian textiles by combining non-invasive techniques, including

81 d approach for fabricating multifunctional e-textiles by integrating conductive two-dimensional (2D)

82 reatly outperforming other radiative heating textiles by more than 3 degrees C.

83 rns on flexible substrates (polymers, paper, textile) by using various printing technologies and post

84 design, the maximum peak power density of 3D textile can reach 263.36 mW m(-2) under the tapping freq

85 These textiles can harvest thermal energy from temperature gra

86 Synthetic textiles can shed numerous microfibers during convention

87 garments to the air and on the influence of textile characteristics including structure, type of yar

88 Polyester garments with different textile characteristics were examined including various

89 oxides NPs was released from abrasion of the textiles coated by the ethanol-based sonochemical proces

90 etal oxide NPs in their applications for the textile coating and provide insight for the safe-by-desi

91 provide the earliest report of MOF-nanofiber textile composites capable of ultra-fast degradation of

92 (composites), whereas the other lab-prepared textiles contain Ag particles on the respective fiber su

93 n- and p-type segments are woven to provide textiles containing n-p junctions.

94 For textiles containing nanosilver, we assessed benefit (ant

95 Cotton is one of the most important textile crops but little is known how microRNAs regulate

96 The 12 textiles demonstrated great variability in MPF release,

97 entions are likely to result from changes in textile design that could reduce emissions to both air a

98 All PV textile devices were characterized under simulated AM 1.

99 These e-textiles display reliable conductivity, enhanced porosit

100 Finally, a potential pathway to 3DP of textiles, dubbed as printing with fibers to create texti

101 for future high-performance biomaterials and textiles due to their high ultimate strength and stiffne

102 mposition of fibers released from functional textiles during accelerated washing were investigated us

103 c fibers released from synthetic (polyester) textiles during simulated home washing under controlled

104 fabrics reduced the extent of Ag release for textiles during subsequent washings.

105 to quantify the amounts of MFs released from textiles during washing.

106 Previously, textile dye sensitised solar cells (DSSCs) woven using p

107 tion (UF) membranes for effective removal of textile dyes from water at a low pressure.

108 ed MuPSs to selectively separate mixtures of textile dyes is shown.

109 Inkjet-printed wearable electronic textiles (e-textiles) are considered to be very promisin

110 Development of multifunctional electronic textiles (e-textiles) with the capacity to interact with

111 ENGs) gives birth to self-powered electronic textiles (e-textiles).

112 hable functions are desirable for numerous e-textile/e-skin optoelectronic applications.

113 bute to high chemical oxygen demand (COD) in textile effluents.

114 successfully achieved the first example of a textile electrode, flexible and truly embedded in a yarn

115 A high-performance, cotton-textile-enabled asymmetric supercapacitor is integrated

116 y >99.9% inhibition of E. coli growth on the textiles, even for textiles that retained as little as 2

117 economically important species for renewable textile fiber production.

118 als in which Ag-NPs were embedded within the textile fibers (composites), whereas the other lab-prepa

119 Identification methods for single textile fibers are in demand for forensic applications,

120 pecies comprise the most important source of textile fibers globally, and these are increasingly grow

121 U hybrid material was spray-coated onto Nyco textile fibers, displaying excellent adhesion to the fib

122 n cultivated worldwide for natural renewable textile fibers.

123 esh while the electrolyte diffuses along the textile fibers.

124 rmal cells are the largest natural source of textile fibers.

125 for the nondestructive forensic analysis of textile fibers.

126 monstrate a method to make common insulating textile fibres conductive, by coating them with graphene

127 We show that this method can be employed to textile fibres of different materials, sizes and shapes,

128 of graphene is not lost when transferred to textile fibres.

129 d melamine (MEL)-based compounds are used in textile finishing as grease, stain, and water repellents

130 ing the functionalization technology used in textile finishing.

131 ld be used as potential PFAS replacements in textile finishing.

132 present a single-layered, ultra-soft, smart textile for all-around physiological parameters monitori

133 rocessed nanoPE is an effective and scalable textile for personal thermal management.

134 nically strong to be woven into a commercial textile for textile based sensors, which can detect magn

135 Using intelligent textiles for clothing represents one possibility for wea

136 ctivities regarding the utilization of smart textiles for harvesting energy from renewable energy sou

137 great significance for next-generation smart textiles for real-time and out-of-clinic health monitori

138 fluctuations to electrical energy, sewn into textiles for use as self-powered respiration sensors, an

139 ast, deamidation was higher in archeological textile fragments from medieval sites ranging from the 9

140 bustly distinguish features belonging to the textile from those due to the underlying object.

141 native and sustainable strategies to achieve textile functionality that do not involve chemical treat

142 The textile generator shows a peak power density of 70 mWm(-

143 the aforementioned criteria toward wearable textile glucose biosensing.

144 The as-fabricated textile glucose biosensors achieved a linear range of 0-

145 decrease of the set-point compared to normal textile, greatly outperforming other radiative heating t

146 ics in freshwaters, and washing of synthetic textiles has been identified as one of their main source

147 The research in 3DP of textiles has lagged behind other areas primarily due to

148 of wearable and large-area energy-harvesting textiles has received intensive attention due to their p

149 electronic, aerospace, wires and cables, and textiles) has been built around them.

150 The printed ssDSSC on textile have been successfully demonstrated and compared

151 Recently, electronic skin and smart textiles have attracted considerable attention.

152 Textiles have been concomitant of human civilization for

153 r, the limited power outputs of conventional textiles have largely hindered their development.

154 biscrolled yarn biofuel cells are woven into textiles having the mechanical robustness needed for imp

155 ading and method of silver attachment to the textile highly influenced the silver release during wash

156 n the use of magnetically modified non-woven textile impregnated with chitosan, was successfully empl

157 s across the surface of a partly aligned CNT textile in air, suspended from its ends.

158 n to contextualize the significance of smart textiles in light of the emerging energy crisis, environ

159 que capabilities of different woven and knit textiles, including zero initial stiffness, full collaps

160 rication processes, such as in the paper and textile industries.

161 automotive, personal care, construction, and textiles industries have recognized cellulose nanomateri

162 a hydrolytic enzyme widely used in food and textiles industries, and for production of bioethanol.

163 thod to obtain lignocellulosic fibers in the textile industry.

164 copper foil, to fibers commonly used by the textile industry.

165 mental pollution and impel sustainability of textile industry.

166 environment from dye pollution caused by the textile industry.

167 A new method for fabricating textile integrable capacitive soft strain sensors is rep

168 (Ag) and silver nanoparticles (Ag-NPs) from textiles into artificial sweat, particularly considering

169 nditions showed that silver remaining on the textile is likely to continue leaching from textiles aft

170 A novel and scalable self-charging power textile is realized by combining yarn supercapacitors an

171 ability, the single-layered ultra-soft smart textile is simultaneously capable of real-time detection

172 Water absorption and transport property of textiles is important since it affects wear comfort, eff

173 The worldwide annual production volume of textiles is nearly one hundred million metric tons.

174 An important phase for ENP associated with textiles is washing.

175 rchers specializing in NGs and those good at textiles, it is rather difficult to achieve fiber/fabric

176 understanding the physical properties of the textile itself to better understand the mechanisms of fi

177 They are used as direct dyes in the textile, leather, printing ink, and cosmetic industries.

178 Reduction of nAg-textile life cycle impacts is not straightforward and de

179 rom a comprehensive literature review of nAg-textile life cycle studies are used to inform a cradle-t

180 ic polymer coating and a solid-state cathode textile loaded with silver oxide.

181 lity to control MPF formation throughout the textile manufacturing chain by using cutting methods whi

182 Our findings show that advanced textile manufacturing combined with scaffold-mediated ge

183 bers into conventional fabrics using typical textile manufacturing techniques.

184 able to adequately explore its potential is textile manufacturing.

185 ents that occur during the various stages of textile manufacturing: from fiber extrusion to assembly

186 biocompatible, implantable, edible commodity textile material.

187 the artificial sweat was negligible for most textiles, meaning that the majority of the released Ag i

188 ications in reinforcing polymers, adhesives, textiles, medical devices, metallic alloys, and even con

189 ath towards flexible, high-aspect ratio, and textile MEMS.

190 tomeric membranes embedded with inextensible textile mesh that inflated to within 10% of their target

191 Additionally, the textile MFC generated consistent power even with repeate

192 The textile MFC used Pseudomonas aeruginosa PAO1 as a biocat

193 scientifically meaningful because developing textile MFCs requires integration of both electronic and

194 at will revolutionize the mass production of textile MFCs.

195 plants, conventional oil and gas extraction, textile mills, and hydraulic fracturing.

196 applied to 13 Buyid silk specimens from the Textile Museum collections.

197 anoscale silver has been applied to consumer textiles (nAg-textiles) to eliminate the prevalence of o

198 The hierarchical structure of the conductive textile network leads to decoupled pathways for oxygen g

199 Among the examined textiles of different ages (13th-17th centuries) and pro

200 this work was to use a panel of 12 different textiles of representative fibers and textile types to i

201 such as liquid metals, nanowires, and woven textiles or on optimally configured 2D/3D structures suc

202 comfort, suggesting great potential in smart textiles or wearable electronics.

203 plication as colorants in paints, cosmetics, textiles, or displays.

204 ustries and consumers importing final goods (Textiles, Other manufactures, Computers, and Machinery).

205 and their applications range from functional textiles over biomedical engineering to high-performance

206 filters, in addition to its use in plastics, textiles, paints, and pesticides.

207 PF release, ranging from 210 to 72,000 MPF/g textile per wash.

208 t the center of the vast majority of ancient textiles preserved under nonextreme conditions, known th

209 d nanogenerator technology with conventional textile processes fosters the emergence of textile-based

210 From global food security to textile production and biofuels, the demands currently m

211 nology, which is compatible with traditional textile production processes.

212 e mat and other related remains suggest that textile products might occur earlier than 7000-8000 year

213 The evolution of the material and textile properties of the surgical mesh was guided by cl

214 nal self-powered sensing capabilities, while textiles provide a versatile flexible design carrier and

215 al scans of the objects with and without the textile provided ground-truth measures of the true physi

216 The generators described here are true textiles, proving active thermoelectrics can be woven in

217 ble and washable field-effect transistors on textile, reaching a field-effect mobility of 91 cm(2) V(

218 exceptional collection of ancient cellulosic textiles recovered in the ancient Near East (4,000 to 5,

219 electrical output properties and outstanding textile-related performances.

220 Moreover, graphene-based e-textiles reported so far are mainly based on graphene de

221 Two among these lab-prepared textiles represent materials in which Ag-NPs were embedd

222 After extraction, papers and textiles retained 64 +/- 28% to 110 +/- 30% of the origi

223 Thanks to these merits, the textile sensor is demonstrated to be able to recognize f

224 The textile sensor unit achieves high sensitivity (14.4 kPa(

225 The epidermal tattoo and textile sensors display a good reproducibility (with RSD

226 ic fiber bundles can serve as ultra-flexible textile sensors.

227 osite shapes by wrapping unfamiliar forms in textile, so that the observable surface relief was the r

228 The self-organized frameworks on textiles (SOFT)-devices detect and differentiate importa

229 Magnetic textile solid phase extraction, based on the use of magn

230 The photos of textile squares with the adsorbed dye were taken with a

231 rited MPFs trapped within the threads or the textile structure.

232 es, dubbed as printing with fibers to create textile structures is proposed for further exploration.

233 Yet, to date, transparent electrodes on a textile substrate have not been explored.

234 or arrays are successfully fabricated on one textile substrate to spatially map tactile stimuli and c

235 A glass fibre textile substrate was used as the target substrate for t

236 over rough surfaces, like those of paper and textile substrates, as well as the complex geometries of

237 r H2S = 0.23 ppm), these constitute the best textile-supported H2S and NO detectors reported and the

238 Using standardized washing tests, textile swatches tailored using five different cutting/s

239 n emerging three-dimensional bioprinting and textile techniques, compares the advantages and shortcom

240 Textile technologies in which fibers containing biologic

241 The 3D textile TENG can also be used as a self-powered active m

242 eral times more than that of conventional 2D textile TENGs.

243 This study was undertaken in a conditioned textile testing laboratory that complies with BS EN ISO

244 We processed the material to develop a textile that promotes effective radiative cooling while

245 nly four amino acids from the venom of Conus textile that strongly potentiated currents of ASIC3, whi

246 ers, characterized as small fibers shed from textiles that are less than 5 mm in size, are a prominen

247 Papers and textiles that are treated with per- and polyfluoroalkyl

248 osthetics, future applications include smart textiles that change breathability in response to temper

249 Woven textiles that change porosity in response to temperature

250 However, neither our skin nor the textiles that make up clothing are capable of dynamicall

251 of E. coli growth on the textiles, even for textiles that retained as little as 2 mug/g Ag after was

252 post-process, particularly suited for these textiles, that selectively removes defective CNTs and ot

253 For all textiles, the MPF release decreased with repeated wash c

254 lexible woven strands that give conventional textiles their characteristic flexibility, thinness, ani

255 s were widely used for decorating historical textiles, their manufacturing techniques have been elusi

256 the greatest environmental impacts of these textiles, there is no data available to support the prop

257 ient microfluidic device based on commercial textile threads.

258 h electronic and fluidic components into the textile three-dimensionally.

259 mans can wear the as-fabricated photovoltaic textile to harness solar energy for powering small elect

260 systems to introduce unique properties, from textiles to biomedical applications.

261 blocks of a broad spectrum of products from textiles to composites, and waveguides to wound dressing

262 he edge- and surface-sourced fibers from the textiles to the total release.

263 omaterials in consumer products ranging from textiles to toys has given rise to concerns over their e

264 r has been applied to consumer textiles (nAg-textiles) to eliminate the prevalence of odor-causing ba

265 conductive binding yarn, a high-power-output textile triboelectric nanogenerator (TENG) with 3D ortho

266 ing the performance of conventional paper or textile-type supercapacitors.With ligand-mediated layer-

267 ferent textiles of representative fibers and textile types to investigate the source(s) of the MPF du

268 0 mu with a similar distribution for the two textile types.

269 nge (log Kow values from -0.80 to 4.05) from textiles, urine, and wastewater.

270 -state dye sensitized solar cell (ssDSSC) on textile using all solution based processes.

271 teristics of strength, flexibility, etc., of textiles, utilizing a fundamentally different manufactur

272 e release of microfibers (MF) from polyester textiles was studied.

273 ant (approximately 0.025 and 0.1 mg fibers/g textile washed, without and with detergent, respectively

274 ed Ag, implying not all Ag-NPs observed in a textile washing study are indicative of released Ag-ENPs

275 embranes display huge potential for treating textile wastewater and other impaired effluents because

276 ations including surgical and medical tools, textiles, water harvesting, self-cleaning, oil spill rem

277 (MALDI-TOF-MS) to study deamidation in wool textiles, we identified eight peptides from alpha-kerati

278 Coated textiles were characterized for their response to variat

279 NPs to human lung due to the abrasion of the textiles were lower or comparable to the minimum doses i

280 al respiratory impact of the NPs, the coated textiles were subjected to the abrasion tests, and the r

281 hnology of inks used on ritual and daily-use textiles, which may have fostered the transfer of metall

282 her and more sophisticated investigations of textiles, which will clarify the origin of metallic ink

283 iew will push forward the frontiers of smart textiles, which will soon revolutionize our lives in the

284 nating two functional components: a bioanode textile with a conductive and hydrophilic polymer coatin

285 ded the fabrication of electronic devices on textile with fully printed 2D heterostructures.

286 ere, we demonstrate a nanophotonic structure textile with tailored infrared (IR) property for passive

287 e, the authors show a nanophotonic structure textile with tailored infrared property for passive pers

288 onal braided (3DB) structure, a TENG-based e-textile with the features of high flexibility, shape ada

289 nces in chemistry and materials, integrating textiles with energy harvesters will provide a sustainab

290 uely generates aligned carbon nanotube (CNT) textiles with individual CNT lengths magnitudes longer t

291 NGs endow smart textiles with mechanical energy harvesting and multifunc

292 The textiles with mechanically processed surfaces (i.e., fle

293 s the basis for future multifunctional smart textiles with passive-cooling functionalities.

294 w direction for multifunctional self-powered textiles with potential applications in wearable electro

295 Combining traditional textiles with triboelectric nanogenerators (TENGs) gives

296 ignificantly more (p-value < 0.001) than the textiles with unprocessed surfaces.

297 nt of multifunctional electronic textiles (e-textiles) with the capacity to interact with the local e

298 The Shanghai Textile Worker Study is a longitudinal study of endotoxi

299 ative asbestos exposure in a cohort study of textile workers in Charleston, South Carolina, followed

300 ing between neighboring coated fibers in the textile yarns.