ライフサイエンスコーパス: nanofiber

1 he same building blocks within a bottlebrush nanofiber.

2 synthesis of a pure (13)C multiwalled carbon nanofiber.

3 nse Au nanoparticle (AuNP) decoration of the nanofibers.

4 tection of atrazine using electrospun SnO(2) nanofibers.

5 ng blocks, which self-assemble into T4P-like nanofibers.

6 ining the beneficial features of electrospun nanofibers.

7 like unidirectionally ordered environment of nanofibers.

8 ther studies) could be used to create silica nanofibers.

9 and the middle layer is filled with vertical nanofibers.

10 40 nm) are homogeneously anchored on carbon nanofibers.

11 on was performed by ALD onto TiO2 coated PAN nanofibers.

12 ammaPNA structures appear to form bundles of nanofibers.

13 s stretched out along with the directions of nanofibers.

14 apsulating route supported on mesoporous WO3 nanofibers.

15 f a film with randomly distributed cellulose nanofibers.

16 ty was found to be highest for ZnO: graphene nanofibers.

17 een limited to the formation of disorganized nanofibers.

18 cally rooted into rigid one-dimensional TiO2 nanofibers.

19 of systems which spontaneously assemble into nanofibers.

20 ing with pure TiO2, TiO2/WO3 and Pt/WO3/TiO2 nanofibers.

21 d the concentration of XO entrapped in Ta2O5 nanofibers.

22 ing process of ultralong bacterial cellulose nanofibers.

23 form precipitous aggregates containing short nanofibers.

24 yield metal nanoparticles located on the gel nanofibers.

25 ics, composites, cellulose nanocrystals, and nanofibers.

26 xylthiophene)s to prepare colloidally stable nanofibers.

27 gle supramolecular nanofibers and bundles of nanofibers.

28 D8(+) T-cell responses in mice than uncapped nanofibers.

29 nted by dendritic cells compared to uncapped nanofibers.

30 e functionalities of polyacrylonitrite (PAN) nanofibers: 1) a substrate for loading active materials,

31 , Ag flakes, Cu nanowires), carbon nanotubes/nanofibers, 2D conductors (e.g., graphene, MoS(2) ), met

32 ial biomedical applications, cytotoxicity of nanofibers against C2C12 premyoblast cells was tested.

33 ing to the large length and the alignment of nanofibers along fiber axis.

34 Branching of nanofibers also leads to improved mechanics of gels and

35 osecond time scales in single supramolecular nanofibers and bundles of nanofibers.

36 esces the inherent advantages of metal-oxide nanofibers and electrochemical transduction techniques,

37 econfigurable 3D network from stiff collagen nanofibers and flexible proteoglycans.

38 ects the micro-pillar bundle, stretching the nanofibers and generating electric charges.

39 METx forms nanofibers and is a partial V2 receptor agonist (determi

40 X was successfully encapsulated in the PDLLA nanofibers and released in a sustained manner.

41 excess amount of the ligands can disrupt the nanofibers and result in the precipitates.

42 cell type and prove the interactions between nanofibers and the death receptors.

43 viors of periodontal ligament (PDL) cells on nanofibers, and antibacterial capabilities of nanofibers

44 ks, including nanoparticles, polymer chains, nanofibers, and nanosheets.

45 function of structural arrangement of the SF nanofibers, and optical-structural-mechanical relationsh

46 As SF nanofibers are aligned parallel undergoing a transition

47 lant extracts incorporated directly into the nanofibers are discussed with illustrations.

48 The nanofibers are further modified with single-stranded pro

49 trating their use as immunotherapies, capped nanofibers are preferentially cross-presented by dendrit

50 Cellulose nanofibers are promising building blocks for future high

51 To date, most nanocarbon materials such as nanofibers are randomly dispersed as a network in a flex

52 Transparent films made of cellulose nanofibers are reported recently.

53 Peptide nanofibers are useful for many biological applications,

54 remarkable birefringence, and highly aligned nanofibers are visible in scanning electronic microscopy

55 le perovskite PrBa0.5Sr0.5Co1.5Fe0.5O5+delta nanofiber as a highly efficient and robust catalyst for

56 The NMR spectrum confirmed stability of nanofiber as there were no interactions between function

57 as its cellular chassis and engineered curli nanofibers as its extracellular matrix component is demo

58 notechnology, specifically nanoparticles and nanofibers, as drug delivery systems for topical and tra

59 some intriguing applications of polyaniline nanofibers, as well as the advantages and remaining chal

60 Taken together, 3D nanofiber assemblies with gradients in pore sizes, fiber

61 one mesenchymal stem cells (BMSCs) on the 3D nanofiber assemblies with smaller pore size show signifi

62 ers can keep the internal V(r) -ReSe(2) @CBC nanofibers away from water coverage, leaving more unoccu

63 Branched aramid nanofibers (BANFs) mimicking polymeric components of bio

64 ive standard deviation for multiple PANi/PEO nanofiber based chemiresistors has been brought down fro

65 The electrospun nanofiber based drug delivery systems have shown tremend

66 evelopment of a generic, robust, electrospun nanofiber based interdigitated chemiresistive platform f

67 progressed in the preparation of electrospun nanofibers based "fast dissolving" drug delivery systems

68 rintlets, nanoparticle-, microparticle-, and nanofiber-based delivery systems for oral and oromucosal

69 application in 3D printed drug products and nanofiber-based drug delivery systems.

70 The voltammetric SMN carbon nanofiber-based immunosensor showed high sensitivity (de

71 CNCs) were obtained from bacterial cellulose nanofibers (BCNFs) by controlled hydrolysis of sulfuric

72 ene nanosheets (GNs) and bacterial cellulose nanofibers (BCNs).

73 zed bacterial cellulose (V(r) -ReSe(2) @CBC) nanofibers between two CBC layers, leading to boosted Fa

74 articles in Ba(Zr(0.21) Ti(0.79) )O(3) (BZT) nanofibers (BFO@BZT_nfs); on the microscopic scale, perc

75 Here, using ECM-mimicking nanofibers bridging cell monolayers, we describe a metho

76 ation allows covalent capture of the aligned nanofiber bundles, enhancing their birefringence and str

77 e not only increases the conductivity of the nanofibers but also pre-concentrates the target analyte

78 rmal welding of nonwoven mats of electrospun nanofibers by introducing a near-infrared (NIR) dye such

79 ng GlyProHyp repeats can readily bind to the nanofibers by triple helical folding, allowing facile di

80 The CHP nanofibers can be a useful tool for detecting and captur

81 mat of nanofibers, melting and fusion of the nanofibers can be employed to fabricate a novel class of

82 lyzed by alkaline phosphatase (ALP), and the nanofibers can be re-formed with subsequent addition of

83 e strong photothermal effect of the dye, the nanofibers can be readily welded at their cross points o

84 The length of the nanofibers can be tuned from micrometers down to 100 nm

85 Both nanoparticles and nanofibers can be used to deliver hydrophobic and hydrop

86 injected intravenously into mice, the small nanofibers can specifically target dColl in the skeletal

87 us fd phage, as a biomolecular biocompatible nanofiber, can be engineered to become capable of first

88 Here, a high-power and durable Co-N-C nanofiber catalyst synthesized through electrospinning c

89 SSCs fabricated with carbon-wrapped VO(2)(M) nanofiber CE showed high power conversion efficiency of

90 a small amount (<=10(-3) wt ratio) of novel nanofiber cellulose (NFC) as a binder to provide suffici

91 A transparent paper made of chitin nanofibers (ChNF) is introduced and its utilization as a

92 work configured with Mo(2) N-mofidied carbon nanofiber (CNF) architecture is established as a Li host

93 lti-wall carbon nanotube (MWCNT), and carbon nanofiber (CNF)) was performed.

94 ough a 3D printing technique using cellulose nanofiber (CNF), which is one of the most earth-abundant

95 Cellulose nanofiber (CNF)-based emulsion coating (CNFC: 0.3% CNF/1

96 quid metal and the specially designed carbon nanofiber (CNF)/SR layer-by-layer cathode, a flexible de

97 bials loaded hydrogels composed of cellulose nanofibers (CNF) and kappa-carrageenan oligosaccharides

98 hemically modified using CD-CuMOF and carbon nanofibers (CNF) composite material to construct a senso

99 lose nanocrystals (CNC) I, CNC II, cellulose nanofibers (CNF) I, and CNF II) were studied by dynamic

100 orous graphene (PG)) and 1D material (carbon nanofibers (CNF)), denoted as PG-C and CNF-C nanocomposi

101 itivity of LFs based on the use of cellulose nanofibers (CNF).

102 ethylenedioxythiophene) (PEDOT), with Carbon Nanofibers (CNFs), we demonstrate a versatile approach f

103 rial prepared from poly-epsilon-caprolactone nanofibers coated on poly-epsilon-caprolactone microfibr

104 nsparent wireless electronics composed of Ag nanofibers coils and functional electronic components fo

105 temperature of the polymer, the pores of the nanofibers collapse due to the nanofibers' microscopic p

106 y (TEM) are combined to demonstrate Sb-based nanofibers composed of bunched yolk-shell building units

107 This nanofiber composite-coating technology could be used to

108 de (Nap-FFKKFKLKL, 1) to form supramolecular nanofibers consisting of alpha-helix.

109 Nanofibers containing the biomass were exposed to soluti

110 e electrochemical analysis of the VO(2)(M)/C nanofiber counter electrode exhibits significant electro

111 xhibited a morphological transformation from nanofibers (dCPT-Sup35) to filaments (CPT-Cap-Sup35) the

112 The results demonstrated an average nanofiber diameter of 502 +/- 150 nm, and the tensile st

113 A tight distribution of the nanofiber diameters could, however, be achieved in the p

114 These matrices consist of curli nanofibers displaying trefoil factors (TFFs), known to p

115 Electrospun polyurethane nanofibers doped with graphene oxide were collected on a

116 re, it is reported that the T4P-like peptide nanofibers efficiently bind metal oxide particles and re

117 red by natural systems, various patterned Ag nanofibers electrodes with a net structure are fabricate

118 rised of poly(lactic-coglycolic acid) (PLGA) nanofibers embedded in a poly(epsilon-caprolactone) (PCL

119 omic layer deposition (ALD) onto polyamide-6 nanofibers enable the formation of conformal Zr-based MO

120 Poly(D,L-lactic acid) (PDLLA) nanofibers encapsulating amoxicillin (PDLLA-AMX) were fa

121 These MOF-functionalized nanofibers exhibit excellent reactivity for detoxifying

122 the nanofiber surface at fixed distance, the nanofibers exhibit high water solubility, without any si

123 rticular, we find that single supramolecular nanofibers exhibit the highest diffusivities reported fo

124 itro drug release of minoxidil sulphate from nanofiber exhibited an initial burst release followed by

125 In summary, we provide evidence of a novel nanofiber-expanded CD34(+) stem cell therapeutic develop

126 erein, we offer an aminated polyethersulfone nanofiber-expanded human umbilical cord blood-derived CD

127 Polymeric nanofibers fabricated by electrospinning either blank (P

128 In this method, a piece of carbon nanofiber film was used as a heater and high treatment t

129 emi-conducting Manganese (III) Oxide (Mn2O3) nanofibers for DNA Hybridization detection.

130 trigger the spherical micelles changing into nanofibers for strong retention in tumor region, consequ

131 alyte species are the specific advantages of nanofibers for this application.

132 quid linalool have been preserved in a solid nanofiber form and designed CD/linalool-IC-NFs confer hi

133 sm to control the length of a supramolecular nanofiber formed by self-assembly of peptide amphiphiles

134 ike the diameter-monodisperse populations of nanofibers formed using analogous DNA approaches, gammaP

135 e cells with patterned nano-arrays of carbon nanofibers forming a nanosensor-cell construct.

136 d by changes in the emission lifetime of the nanofiber from the nanosecond to microsecond regime.

137 Here we prepare bottlebrush nanofibers from an acridine- and triazine-based donor/ac

138 es the preparation of robust, multicomponent nanofibers from general building blocks, combining their

139 composite yarn production whereby a plume of nanofibers generated by high throughput AC needleless an

140 z., drop casting of graphene doped Mn(2)O(3) nanofibers (GMnO) and direct electrospinning of polyanil

141 anisotropic film with well-aligned cellulose nanofibers has a mechanical tensile strength of up to 35

142 ynthesized red-phosphorus-impregnated carbon nanofibers has been proven to be an effective method to

143 sensing probe coated with XO entrapped Ta2O5 nanofibers has been turned out to possess maximum sensit

144 nocomposite systems based on one-dimensional nanofibers has shown great potential in achieving a high

145 The PVDF/GO/q-PMMA-b-PDMAEMA@PVA nanofibers has superhydrophilic properties (water contac

146 In this study, the nanofibers have been characterized using Field Emission

147 Z-scheme TiO2/WO3 heterostructure composite nanofibers have been fabricated, which even exhibited ex

148 Polymeric electrospun nanofibers have extensive applications in filtration, se

149 line/polyethylene oxide (PANi/PEO) composite nanofibers, have been utilized to decorate these electro

150 In vitro, KMP2 formed a cross-linked nanofiber hydrogel to encapsulate MSC-EVs.

151 The well-aligned cellulose nanofibers in natural wood are maintained during deligni

152 The cellulose nanofibers in our engineered material backscatter solar

153 significantly enhance the absorption of ZnO nanofibers in the range of visible-light.

154 ic degree of cell alignment templated by the nanofibers in vitro.

155 Thermal analysis of nanofibers indicated no chemical interaction.

156 spacing in suspended crosshatch networks of nanofibers induces cells to exhibit plasticity in migrat

157 PDLLA-AMX nanofibers inhibited bacterial growth and promoted the v

158 ) and CATCH(-) coassemble into two-component nanofibers instead of self-sorting.

159 Here, biomimetic composites from aramid nanofibers interlaced with poly(vinyl alcohol), with wat

160 of the six immunosensors suggest that carbon nanofiber is a better electrode material for the SMN imm

161 3D assemblies consisting of radially aligned nanofibers is prepared by dripping, diffusion, and cross

162 The single crystal structure of the CAM-Ag nanofibers is solved in the space group P1, with the asy

163 t lengthwise assembly of these peptides into nanofibers is typically difficult to control, resulting

164 rogeneous "irradiated-pristine" polyethylene nanofiber junction as a nanoscale thermal diode, in whic

165 Herein, we report a series of MOF-nanofiber kebab structures for fast degradation of CWAs.

166 one near the hydrophobic core of cylindrical nanofibers leads to strong anion-pi interactions between

167 ngths and an incomplete understanding of how nanofiber length affects biological responses.

168 ation from short CAM nanorods to long CAM-Ag nanofibers (length over 1000 mum), accompanied by tautom

169 ion in tumor region, consequently the linear nanofibers long locate and sustainably release drugs.

170 The q-PMMA-b-PDMAEMA in the nanofiber matrix was confirmed by C=O bands (1734 cm(-1)

171 ove the performance of polymeric electrospun nanofiber mats (ENMs) for equilibrium passive sampling a

172 nd imprint imaging using electrospun nylon-6 nanofiber mats are demonstrated for various analytical c

173 its with their faithful reproductions on the nanofiber mats is illustrated with suitable examples.

174 ense, hydrophilic polymers on to electrospun nanofiber mats.

175 Using these materials, nanofibers may be prepared which (i) strongly exhibit TS

176 ithin the volume of a supramolecular peptide nanofiber measuring 6.7 nm in diameter.

177 the mechanical strength of a nonwoven mat of nanofibers, melting and fusion of the nanofibers can be

178 strated the effectiveness of P-Tris affinity nanofiber membrane for the recovery of lysozyme from com

179 Polyacrylonitrile nanofiber membrane functionalized with tris(hydroxymethy

180 y alkaline hydrolysis of a polyacrylonitrile nanofiber membrane prepared by electrospinning process.

181 uir model, the adsorption capacity of P-Tris nanofiber membrane was estimated to be 345.83 mg/g.

182 iber organizations is formed by expanding 2D nanofiber membranes composed of multiple regions collect

183 are described for converting 2D electrospun nanofiber membranes to 3D hierarchical assemblies with s

184 brane chromatography with three-layer P-Tris nanofiber membranes, the optimal operating conditions we

185 l substrates such as natural fibers, polymer nanofibers, mesoporous materials, graphene, viruses and

186 pores of the nanofibers collapse due to the nanofibers' microscopic polymer chain relaxing and packi

187 We used bacteriophage as a nanofiber model system to exploit its liquid crystalline

188 etection response of copper-doped zinc oxide nanofiber modified electrode shows excellent sensitivity

189 in based on covalently functionalized carbon nanofiber-modified screen printed electrodes.

190 the virus nucleocapsid (N) protein on carbon nanofiber-modified screen-printed electrodes which were

191 re directly dropped on the surface of carbon nanofiber-modified screen-printed electrodes.

192 Further, the nanofiber morphology enhances its mass activity remarkab

193 f-assemble into peptide nanofibers; with the nanofiber morphology protecting the peptide from plasma

194 cturally defined nanoscale objects including nanofibers, nanotubes, and nanosheets.

195 epts of 1D-photoanodes (nanotubes, nanorods, nanofibers, nanowires) based on titania, hematite, and o

196 on of representative classes of 3D-inorganic nanofiber network (FN) films by a blow-spinning techniqu

197 ns at nanomaterial interfaces, the composite nanofiber network can adapt itself under stress, enablin

198 The DNA nanofiber networks and the bactericidal histone constitu

199 Crosshatch nanofiber networks of tunable interfiber spacing induce

200 produced, either forming stable interfacial nanofiber networks with remarkable stability, or more co

201 ociated by EDTA to afford the unshelled P3HT nanofiber networks, and restored by treatment of bifunct

202 -dimensional structure, in which all of PANI nanofibers (NFs) are tightly wrapped inside reduced grap

203 lyst, i.e., Mn(2+)-doped and N-decorated ZnO nanofibers (NFs) enriched with vacancy defects, fabricat

204 talysts onto semiconductor metal oxide (SMO) nanofibers (NFs) via electrospinning for markedly enhanc

205 (vinylidene difluoride) (PVDF)/dopamine (DA) nanofibers (NFs) with a very high beta-phase content and

206 In this paper, BaTiO3 nanofibers (NFs) with different aspect ratio were synthe

207 e (FMR) under an electric field in a coaxial nanofiber of nickel ferrite (NFO) and lead zirconate tit

208 erved following uniaxial extension of the FN nanofibers of 2-fold relative to the patterned state.

209 together, result in the localization of the nanofibers of D-tetrapeptides for killing the cancer cel

210 olorimetric pH indicator was developed using nanofibers of poly(lactic acid) (PLA) and polyethylene o

211 Metallized organic nanofibers of the type described here offer the possibil

212 n amyloid like-bovine serum albumin (AL-BSA) nanofibers on QCM surfaces.

213 metal electrodes decorated with electrospun nanofibers on the top.

214 Polyaniline nanofibers, on the other hand, have demonstrated, throug

215 her raises the polarization of the composite nanofibers; on the mesoscopic scale, orthotropic orienta

216 oms in the vicinity of a single-mode optical nanofiber (ONF) that coherently exchange evanescently co

217 hile the hydrogelators self-assemble to form nanofibers or nanoribbons that are unable to bind with t

218 cement by the high specific strength ceramic nanofibers or nanowires (NWs) with high aspect ratios.

219 By using an electrospun polyacrylonitrile nanofibers packed ITEX, selective extraction of some VOC

220 We report the fabrication of polyaniline nanofiber (PANI)-modified screen-printed electrode (PANI

221 f the CcO in a network of hydrophobic carbon nanofibers permits a direct electrochemical communicatio

222 ls was selected for reactions on Polypyrrole nanofibers (PPy-NF) in presence of microwave irradiation

223 ion into shortened hollow graphitized carbon nanofibers (PtNP@S-GNF) toward the oxygen-reduction reac

224 Membranes with PDLLA-AMX nanofibers reduced inflammation and accelerated periodon

225 For the nanofiber samples measured here, we observe a maximum th

226 yolk-shell Sb@C nanoboxes embedded in carbon nanofibers (Sb@CNFs).

227 To this end, a polymeric nanofiber scaffold culture system was established to dev

228 can be functionalized within an electrospun nanofiber scaffold, thereby creating multiheterojunction

229 opharmaceutical production and manufacturing nanofiber scaffolds for tissue engineering.

230 Prepared nanofibers showed a 47.4% encapsulation efficiency and 7

231 The wettability analysis of the nanofibers showed hydrophilicity (zero angle with water)

232 spatial hydrogen bond density, the effect of nanofiber size and orientation on the fracture toughness

233 Significantly, the CAM-Ag nanofibers spontaneously assemble into a free-standing m

234 were then used to prepare multiblock organic nanofibers structurally analogous to nanoscale RGB pixel

235 ve-residue peptides that form hydrogels with nanofiber structures.

236 puts high density of hydrophilic CHPs on the nanofiber surface at fixed distance, the nanofibers exhi

237 to the Mercaptopropylphosphonic acid treated nanofiber surface due to inherent electric field generat

238 phobic interior and immobilized water on the nanofiber surface.

239 cancies and nitrogen are introduced into the nanofibers surface.

240 ial type IV pili (T4P) are polymeric protein nanofibers that have diverse biological roles.

241 ydrogelator that self-assembles to form long nanofibers, the presence of the ligand-receptor interact

242 using any non-solvent liquids, porous carbon nanofiber/thermoplastic polyurethane (CNF/TPU) nanocompo

243 Owing to the self-functionality of AL-BSA nanofibers, these modified QCM surfaces were directly ac

244 edded in freestanding N -doped porous carbon nanofibers thin film (Se@NPCFs) as cathode.

245 rol of the alignment or directionality of SF nanofibers through an electrospinning procedure.

246 report the synthesis of germanium-zinc alloy nanofibers through electrospinning and a subsequent calc

247 cal properties on the alignment of cellulose nanofibers through the film thickness direction.

248 bovine serum albumin (BSA), titanium dioxide nanofibers (TiO2NFs) and carboxylic acid functionalized

249 The piezoelectric nature of a single nanofiber tip link is confirmed by X-ray diffraction (XR

250 polyvinylidenefluoride (PVDF) piezoelectric nanofiber tip links.

251 nanocomposite consisting of titanium dioxide nanofibers (TNFs) and graphene oxide nanosheets (GONs) f

252 entrations needed to induce assembly enabled nanofibers to be obtained by touch-spinning, which exhib

253 ddition, the multivalency of CHPs allows the nanofibers to bind to dColl in vitro and in vivo with ex

254 f microalgal biomass encapsulated in polymer nanofibers to develop a colorimetric pH indicator.

255 light on how barnacles use low complexity in nanofibers to enable adhesion, and serves as a starting

256 roxyphenylalanine) allows the self-assembled nanofibers to form an anisotropic hydrogel string under

257 rolling the length of supramolecular peptide nanofibers to modulate their immunogenicity in the conte

258 designed peptides bind the tips of elongated nanofibers to shorten and narrow their length distributi

259 (FE) models for diffusive drug release from nanofibers to the three-dimensional (3D) surrounding med

260 Self-junctioned copper nanofiber transparent flexible films are produced using

261 o increased cross-presentation, these capped nanofibers trigger stronger CD8(+) T-cell responses in m

262 We found that the FN nanofibers underwent 3.3-fold and 9-fold changes in leng

263 bles to form nanoparticles, which turns into nanofibers upon partial dephosphorylation catalyzed by e

264 tion of uniform polymer and composite micro-/nanofibers using a microfluidic gas flow focusing nozzle

265 In this study, we engineered monodisperse FN nanofibers using a surface-initiated assembly technique

266 ated with embedded vertically aligned carbon nanofibers (VACNFs) are functionalized with specific pep

267 e of one-dimensional carbon wrapped VO(2)(M) nanofiber (VO(2)(M)/C) as a cost-effective counter elect

268 length and width, respectively, and that the nanofiber volume was conserved.

269 The optimized value of f in ZnO: graphene nanofiber was reconfirmed using UV-vis spectroscopy.

270 Stability studies revealed that minoxidil nanofiber was stable if stored at room temperature and p

271 Uniform short length nanofiber was synthesised by a sol-gel based simple and

272 e TiO2 protective layer on the PAN polymeric nanofibers was presented as an effective route to enhanc

273 ectively, while these values for CA/Gel/Beri nanofibers were 2.69 +/- 0.05 MPa, 56.93 +/- 1 degrees ,

274 ermeability and water uptake ratio of CA/Gel nanofibers were around 2.83 +/- 0.08 MPa, 58.07 +/- 2.35

275 anofibers, and antibacterial capabilities of nanofibers were evaluated in vitro.

276 First, P3HT-SH nanofibers were formed due to interchain pi-pi stacking.

277 FN nanofibers were patterned on surfaces in a pre-stressed

278 anorods, nanotubes and nanowires while Ta2O5 nanofibers were prepared by electrospinning technique.

279 nanocomposites, nanoflowers, nanotubes and nanofibers were prepared using optimized value of f.

280 Upon the addition of AuNRs-DDT, P3HT-SH nanofibers were transformed into nanoribbons decorated w

281 sting method, which consisted of a cellulose nanofiber/whey protein matrix containing titanium dioxid

282 Due to the molecular architecture of the nanofibers which puts high density of hydrophilic CHPs o

283 osites filled with the orthotropic composite nanofibers, which is by far the highest value achieved i

284 ng to the improved flexibility of the CAM-Ag nanofibers with bonded chain structure, and can be rever

285 samples, such as cellulose nanocrystals and nanofibers with cellulose I and II structures (cellulose

286 al modeling reveal that the film consists of nanofibers with crystalline and amorphous regions, and t

287 monolithic mats, containing highly entangled nanofibers with diameters of 9.2 +/- 3.7 nm, thereby ach

288 -assembly of thiol-terminated P3HT (P3HT-SH) nanofibers with dodecanethiol-coated AuNRs (AuNRs-DDT).

289 olution that enabled coalignment of scaffold nanofibers with endogenous myofibers.

290 harge-transporting materials to give organic nanofibers with ordered structures mimicking that of mul

291 composing relaxor Ba(Zr(0.21) Ti(0.79) )O(3) nanofibers with P(VDF-TrFE-CFE) to make relaxor-relaxor-

292 The creation of 1D pai-conjugated nanofibers with precise control and optimized optoelectr

293 n self-assembly of nonaggregating beta-sheet nanofibers with precise structure.

294 trates a bioinspired way to generate peptide nanofibers with predefined secondary structures of the p

295 most viable approach for the fabrication of nanofibers with several beneficial features that are ess

296 ynthesized red-phosphorus-impregnated carbon nanofibers with the corresponding chemo-mechanical simul

297 ptides control the length of helical peptide nanofibers with unique precision.

298 peptide prodrugs self-assemble into peptide nanofibers; with the nanofiber morphology protecting the

299 micro/nano-elements (i.e. nanoparticles and nanofibers) without much altering their relative spatial

300 mer fibers; nanocomposite actuators; twisted nanofiber yarns; thermally activated shape-memory alloys