ライフサイエンスコーパス: textile

1 ated filament material (filter paper, cotton textile).

2 he venom gland of a single cone snail (Conus textile).

3 ner by fabricating an all-solid photovoltaic textile.

4 the impacts associated with nanoenabling the textile.

5 1 conotoxin tx3a found in the venom of Conus textile.

6 la-TxX and Gla-TxXI, from the venom of Conus textile.

7 enom of the molluscivorous cone snail, Conus textile.

8 he valve opens and the liquid penetrates the textile.

9 e liquid cannot pass through the hydrophobic textile.

10 r is required to control bacterial growth in textiles.

11 ase more particulate Ag than conventional Ag textiles.

12 ciation and release upon use of nanoenhanced textiles.

13 ble textiles and for six laboratory-prepared textiles.

14 m composites in comparison to surface-coated textiles.

15 sensitive flexible materials like papers and textiles.

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

17 , knotted, or woven into flexible electronic textiles.

18 le devices for wearable electronics or smart textiles.

19 g seed trichomes ('fibers') used for premium textiles.

20 sed extensively to flame-retard polymers and textiles.

21 ng those embedded in flexible substrates and textiles.

22 ing natural fiber used in the manufacture of textiles.

23 that operate based on electrowetting through textiles.

24 orine remains associated with the papers and textiles.

25 t of the methods used to produce macroscopic textiles.

26 the context of total fluorine for papers and textiles.

27 l stimuli, are essential components of smart textiles.

28 hahrbanu site in Iran unearthed several silk textiles.

29 ld integrated electronic devices directly in textiles.

30 h energy density that can be integrated into textiles.

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

32 building insulation foams, electronics, and textiles.

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

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

35 e vitamin K-dependent carboxylase from Conus textile, a marine invertebrate, we hypothesized that str

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

37 hly conductive and flexible activated carbon textiles (ACTs) for energy-storage applications.

38 mited to NOAA, but can be used for any other textile additive.

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

40 e venoms of the molluscivorous species Conus textile and Conus marmoreus all have a characteristic pa

41 iomedical/medical fields to food, packaging, textile and household material.

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

43 de bridges of a natural peptide tx3c from C. textile and synthetic peptide mr3a from C. marmoreus sho

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

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

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

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

48 ne (heretofore not reported in pre-Columbian textiles) and luteolin glycosides, though a specific pla

49 have been observed near cities and polymer, textile, and electronics manufacturing centers.

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

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

52 ermally sensitive substrates, such as paper, textiles, and plastics.

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

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

55 ws and outflows such as the agrarian sector, textiles, and the agri-food industry are examined in det

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

57 Textiles are among the longest and most widespread techn

58 tion and characterization of highly flexible textiles are reported.

59 in macroscopic materials (cables, ropes, and textiles) as well as synthetic and biological nanomateri

60 mmercial lake pigments, and fibers from dyed textiles, as well as actual aged samples, such as micros

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

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

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

64 que is introduced for age estimation of silk textiles based on amino acid racemization rates.

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

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

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

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

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

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

71 hnologies involving knotted netting, such as textiles, basketry, and cordage, in the Upper Paleolithi

72 TiO(2) is used in textiles because of its UV-absorbing properties and as p

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

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

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

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

77 osure pathways, dermal exposure to NOAA from textiles can be considered comparably minor for TiO2-NOA

78 These textiles can harvest thermal energy from temperature gra

79 Synthetic textiles can shed numerous microfibers during convention

80 = Gal-GalNAc-threonine), isolated from Conus textile, causes hyperactivity and spasticity when inject

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

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

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

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

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

86 For textiles containing nanosilver, we assessed benefit (ant

87 Textiles containing TiO2 for UV protection did not relea

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

89 These e-textiles display reliable conductivity, enhanced porosit

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

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

92 rst case scenario for wearing functionalized textiles during sports activities.

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

94 ease of TiO(2) from six different functional textiles during washing.

95 s and their complexes that have been used as textile dyes and pigments in paintings and other polychr

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

97 n HPLC-DAD-MS method is described to analyze textile dyes in different dye classes (reactive, basic,

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

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

100 seed germination and decolorized industrial textile effluent, suggesting the enzyme may be valuable

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

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

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

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

105 We have developed or improved upon two mild textile extraction methods that use ethylenediaminetetra

106 latform that enables separation of dyes from textiles, extraction of dyes from aqueous solution, and

107 Herein, a direct analysis of dyed textile fabric was performed using the infrared matrix-a

108 tum) provides the world's dominant renewable textile fiber, and cotton fiber is valued as a research

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

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

111 ch are incorporated more or less intact into textile fibers during dyeing.

112 The forensic analysis of textile fibers uses a variety of techniques from microsc

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

114 for the nondestructive forensic analysis of textile fibers.

115 as used to identify various dyes in finished textile fibers.

116 esh while the electrolyte diffuses along the textile fibers.

117 dyed reference fibers, as well as historical textile fibers.

118 s been widely studied to produce polymer and textile fibers.

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

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

121 c zinc oxide nanowires grown radially around textile fibres.

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

123 ing the functionalization technology used in textile finishing.

124 structural elements (e.g., mats, laminates, textiles, foams and composites).

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

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

127 Using intelligent textiles for clothing represents one possibility for wea

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

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

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

131 ass of flame retardants historically used in textiles, furniture, and electronic products.

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

133 The sun-protection textiles had Ultraviolet Protection Factors that were be

134 The carboxylase cDNA from Conus textile has an ORF that encodes a 811-amino-acid protein

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

136 Multifunctional applications of textiles have been limited by the inability to spin impo

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

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

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

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

141 stry, have now been embraced by the food and textile industries and are finding geochemical and envir

142 dustrially important in the food, paper, and textile industries but also a potentially useful method

143 ed 18 to 49 years working in the diamond and textile industries in Surat city.

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

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

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

147 mportant source of natural fibre used in the textile industry and the productivity of the crop is adv

148 ations between occupational exposures in the textile industry and the risks of esophageal cancer and

149 There is a growing need in the textile industry for more economical and environmentally

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

151 mental pollution and impel sustainability of textile industry.

152 b-exposure matrix developed for the Shanghai textile industry.

153 thod to obtain lignocellulosic fibers in the textile industry.

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

155 Mobilization and migration of ENPs from the textile into human sweat can result in dermal exposure t

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

157 veloped to convert insulating cotton T-shirt textiles into highly conductive and flexible activated c

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

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

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

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

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

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

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

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

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

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

168 ors (OR 1.3 [95% CI 1.1-1.5]), miscellaneous textile machine operators (OR 1.2 [95% CI 1.0-1.4]), and

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

170 Elimia proxima), collected downstream from a textile manufacturing outfall, exhibited TBB, TBPH, and

171 analyze lung cancer mortality in a cohort of textile manufacturing workers who were occupationally ex

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

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

174 t morphologies and functions within a single textile membrane, enabling scientists to engineer the pr

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

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

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

178 The textile MFC used Pseudomonas aeruginosa PAO1 as a biocat

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

180 at will revolutionize the mass production of textile MFCs.

181 turing; utilities; office building services; textile mill products manufacturing; the armed forces; f

182 mothers of liveborn singletons who worked in textile mills in Anqing, China, from 1996 to 2000.

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

184 A number of pre-Columbian textiles, most discovered in northern Peru and dating to

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

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

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

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

189 Analysis of dyes extracted from textiles of historical interest can give valuable inform

190 Out of four investigated textiles, one T-shirt and one pair of trousers with clai

191 s for potential use in future nanowire-based textiles or in solar photovoltaics.

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

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

194 vapor deposition offer new opportunities in textile photovoltaics and optoelectronics, as exemplifie

195 Industrial wastewaters such as tannery and textile processing effluents are often characterized by

196 cal convergence, and knowledge of industrial textile processing is being combined with new developmen

197 ibres was seen and addressed in conventional textile production a century ago.

198 Finally, the analysis of textile products exemplarily demonstrates the applicabil

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

200 neered systems from nanotextured surfaces to textile products, where they offer benefits in filtratio

201 ke them suitable for uses such as composite, textile, pulp and paper manufacture.

202 cid, the technique is capable of dating silk textiles ranging in age from several decades to a few-th

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

204 The results indicate that functional textiles release some TiO(2) particles, but that the amo

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

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

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

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

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

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

211 After 10 washings, only in two textiles significantly lower Ti contents were measured.

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

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

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

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

216 Five of the textiles (sun-protection clothes) released low amounts o

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

218 (ENP) are increasingly used to functionalize textiles taking advantage, e.g., of the antimicrobial ac

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

220 Textile technologies in which fibers containing biologic

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

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

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

224 racterized a peptide from the venom of Conus textile that makes normal mice assume the phenotype of a

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

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

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

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

229 Woven textiles that change porosity in response to temperature

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

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

232 IX, from the venom of the marine snail Conus textile, the cDNA encoding this peptide was cloned from

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

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

235 ient microfluidic device based on commercial textile threads.

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

237 They also provide textiles, timber, and potentially second-generation biof

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

239 o NOAA migrating from commercially available textiles to artificial sweat by an experimental setup th

240 mestication and have a variety of uses, from textiles to biomedical materials.

241 commercial products, from lumber, paper and textiles to thickeners, films and explosives.

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

243 (Limulus polyphemus), and cone snail (Conus textile) to compare these structures to the known bovine

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

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

246 We now have found that venom from Conus textile triggers a similar prolonged discharge, and we h

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

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

249 f synaptic stimulation, or exposure to Conus textile venom (CtVm), triggers an afterdischarge in the

250 A encoding this peptide was cloned from a C. textile venom duct library.

251 dependent gamma-glutamyl carboxylase from C. textile venom ducts.

252 ctroscopy of native tx5a isolated from Conus textile was then used to determine that the glycan prese

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

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

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

256 HRTB for removing metals commonly present in textile wastewaters (chromium, manganese, cobalt) was in

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

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

259 Coated textiles were characterized for their response to variat

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

261 e information as to where, when, and how the textiles were made.

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

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

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

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

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

267 Thus, extraction of textiles with EDTA or formic acid reagents can yield sig

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

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

270 One textile (with antimicrobial functionality) released much

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

272 more hydrogen bonds to external molecules in textiles, wood, paper and the living plant.

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

274 ality in a cohort of South Carolina asbestos textile workers (1940-2001).

275 workers, and 70-85% of the original 472 silk textile workers (as a control group).

276 processors (OR = 8.62, 95% CI: 0.86, 86.5), textile workers (OR = 4.70, 95% CI: 0.29, 77.1), electri

277 s of lung cancer mortality among 1) asbestos textile workers and 2) uranium miners.

278 Three-hundred sixty-four textile workers from Anqing, China, who conceived at lea

279 tos exposure and lung cancer mortality among textile workers illustrate this approach.

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

281 ses in 388 newly married, nonsmoking, female textile workers in China between 1996 and 1998.

282 ort of 526 newly married, nonsmoking, female textile workers in China between 1996 and 1998.

283 e investigated in a cohort of 265,402 female textile workers in Shanghai, China, who were interviewed

284 ast cancer within a cohort of 267,400 female textile workers in Shanghai, China.

285 se-cohort study nested in a cohort of female textile workers in Shanghai, China.

286 tton dust, a 15-yr follow-up study in cotton textile workers was performed in Shanghai, China from 19

287 or astrocytic tumors only, while messengers, textile workers, aircraft operators, and vehicle manufac

288 rates were 76-88% of the original 447 cotton textile workers, and 70-85% of the original 472 silk tex

289 itude and severity of chronic impairments in textile workers.

290 as present in dry lake pigment grains, dyed textile yarns, and reference paint layers containing the