ライフサイエンスコーパス: nanofiber

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

2 n substrate yield the Young's modulus of the nanofiber.

3 like unidirectionally ordered environment of nanofibers.

4 yield metal nanoparticles located on the gel nanofibers.

5 and the middle layer is filled with vertical nanofibers.

6 ochemically depositing pseudocapacitive MnO2 nanofibers.

7 peptides that self-assemble in water to form nanofibers.

8 eads to produce highly loaded, fine magnetic nanofibers.

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

10 cal devices, nanoparticles, quantum dots and nanofibers.

11 imensional (1D) ultralong and ultrathin TiO2 nanofibers.

12 imit of sensitivity, we have used individual nanofibers.

13 EEVV result in the formation of cylindrical nanofibers.

14 with silicon chips and low-cost electrospun nanofibers.

15 to further self-assemble into collagen-like nanofibers.

16 40 nm) are homogeneously anchored on carbon nanofibers.

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

18 apsulating route supported on mesoporous WO3 nanofibers.

19 f a film with randomly distributed cellulose nanofibers.

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

21 een limited to the formation of disorganized nanofibers.

22 cally rooted into rigid one-dimensional TiO2 nanofibers.

23 of systems which spontaneously assemble into nanofibers.

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

25 d the concentration of XO entrapped in Ta2O5 nanofibers.

26 ing process of ultralong bacterial cellulose nanofibers.

27 form precipitous aggregates containing short nanofibers.

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

29 reduced by the hydroxyl groups of cellulose nanofibers, acting as the reducing agent producing a bio

30 stals are obtained at the tips of the carbon nanofibers after sintering at 1500 degrees C and atmosph

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

32 of the macroscopic mechanical properties of nanofibers aligned in arrays, whose Young's modulus is s

33 ocols for the fabrication and preparation of nanofibers aligned on glass coverslips for the study of

34 Nanofiber alignment considerably increased analyte migra

35 nhibitory regulators were achieved by either nanofiber alone (20-40%, p<0.05) or the synergistic inte

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

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

38 esulting approach and retract curves on both nanofiber and silicon substrate yield the Young's modulu

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

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

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

42 for batch or continuous formation of polymer nanofibers and other nanomaterials in the bulk of a shea

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

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

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

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

47 ds for the drawing of nanofibers, core-shell nanofibers, and their aligned 2D and 3D meshes using pol

48 Ultimately, unmodified TiO2 nanofibers appear most promising for use as reactive fil

49 ith their straight counterparts, the crimped nanofibers are able to mechanically mimic native tendon

50 As SF nanofibers are aligned parallel undergoing a transition

51 Electrosprayed nanoparticles and electrospun nanofibers are both employed as natural or synthetic car

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

53 These complementary n- and p-nanofibers are endowed with ionic groups with opposite c

54 Cellulose nanofibers are promising building blocks for future high

55 Transparent films made of cellulose nanofibers are reported recently.

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

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

58 m diameter template-synthesized polyfluorene nanofibers as nanoscale detection elements.

59 ults in spontaneously aligned supramolecular nanofibers as the matrices of a monodomain hydrogel that

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

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

62 ofibril composites were composed of template nanofibers, assembled from an electron acceptor molecule

63 The H6-based nanofiber assemblies encapsulated camptothecin (CPT) wit

64 In combination with the nanofiber-assisted layer-by-layer cell assembly, the pat

65 asily scaled up to the fabrication of staple nanofibers at rates that may exceed tens of kilograms pe

66 self-organized separately obtaining n- and p-nanofibers at the same scale.

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

68 iomarker for cardiac disease, using a carbon nanofiber based biosensor platform.

69 igh-yield and scalable preparation of chiral nanofibers based on the self-assembly of various ultrath

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

71 A carbon nanofiber-based label free electrochemical immunosensor

72 Impressively, the chiral MoS(2) nanofiber-based memory device presents a typical nonvola

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

74 Free-standing carbon-coated Si nanofiber binderless electrodes produce a capacity of 80

75 Nanofibers borne from zirconia lack an observable graphi

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

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

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

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 The obtained chiral nanofibers can be further transformed to same-handed chi

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

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

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

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

86 bel-free biosensor is presented using carbon nanofiber (CNF) nanoelectrode arrays for the detection o

87 oxy nanocomposites with magnetite and carbon nanofiber (CNF) nanohybrids, without any surface modific

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

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

90 Porous carbon nanofiber (CNF)-supported tin-antimony (SnSb) alloys are

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

92 Cellulose nanofibers (CNF) were used to immobilize PB via the crea

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

94 sed on an array of vertically aligned carbon nanofibers (CNFs) grown by plasma enhanced chemical vapo

95 trospun polyacrylonitrile (PAN) based carbon nanofibers (CNFs) have attracted intense attention due t

96 The effect of cellulose nanofibers (CNFs) on flow, hydration, morphology, and st

97 nd at a steel cathode into CNTs or carbon or nanofibers, CNFs.

98 rphological features of carbon nanotubes and nanofibers (CNTs and CNFs) grown from zirconia nanoparti

99 We use nanofibers coated with N-WASP WWCA domains as model cell

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

101 This nanofiber composite-coating technology could be used to

102 ivated N-doped hollow carbon-nanotube/carbon-nanofiber composites are prepared having a superhigh spe

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

104 nd brush-spinning methods for the drawing of nanofibers, core-shell nanofibers, and their aligned 2D

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

106 The used TiO2 nanofibers deposited with Cu were reclaimed directly as

107 Moreover, isotopic dilution of labeled MAX8 nanofibers did not result in a loss of the (13)C-(13)C d

108 Here we present Biofilm-Integrated Nanofiber Display (BIND) as a strategy for the molecular

109 a 3D printed bioceramic scaffold with phage nanofibers displaying high-density RGD peptide.

110 Using poly(epsilon-caprolactone) nanofibers, efficient knockdown of OL differentiation in

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

112 The addition of meshes of nanofibers embedded in their matrix forms a composite th

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

114 olymeric materials, and particularly polymer nanofibers, enable the manipulation of the functional mo

115 These MOF-functionalized nanofibers exhibit excellent reactivity for detoxifying

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

117 ombining lotus root-like multichannel carbon nanofibers 'filling' and amino-functionalized graphene '

118 In this study, we used an aligned nanofiber film that mimics the nanotopography in the tum

119 gnificantly reduced when cultured on aligned nanofiber films compared to smooth and randomly aligned

120 ilms compared to smooth and randomly aligned nanofiber films.

121 s have inspired the design of self-assembled nanofibers for applications in regenerative medicine, dr

122 des new opportunities for the fabrication of nanofibers for biomedical applications.

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

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

125 aying or electrospinning of nanoparticles or nanofibers for tissue engineering or drug delivery/pharm

126 verview of the use of both nanoparticles and nanofibers for topical drug delivery.

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

128 by atomic force microscopy shows consecutive nanofiber formation and shortening.

129 ge is a challenge for the common methods for nanofiber formation.

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

131 shion in the mesogens and the self-assembled nanofibers formed in the gelation process.

132 l complex in the hydrogelator results in the nanofibers, formed by the self-assembly of the hydrogela

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

134 different transducer platforms showed carbon nanofiber gave higher current signal response than singl

135 carbon nanofibers-->well crystallined carbon nanofibers-->bent graphitic sheets-->onion-liked rings--

136 nism as follows: the disorder "solid" carbon nanofibers-->well crystallined carbon nanofibers-->bent

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

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

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

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

141 Direct writing of hierarchical micro/nanofibers have recently gained popularity in flexible/s

142 ibrillated cellulose and bacterial cellulose nanofibers, have become fascinating building blocks for

143 irectly write diversified hierarchical micro/nanofibers in a continuous and programmable manner.

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

145 her, the results demonstrate the efficacy of nanofibers in providing topographical cues and microRNA

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

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

148 roup that self-assembles into highly charged nanofibers in water and orders into two-dimensional crys

149 turn into self-assembling molecules to form nanofibers in water.

150 and implanted into a bone defect, the phage nanofibers induce osteogenesis and angiogenesis by activ

151 d rethreading of the molecular components in nanofibers induced by exposure to base and acid vapors,

152 the high charge density around the aggregate-nanofiber interface, which hinders the charge separation

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

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

155 A highly crystalline polyethylene nanofiber is deflected by a cantilever under an atomic f

156 ngle-cell migration along fibronectin-coated nanofibers is associated with lateral actin-based waves.

157 biofunctionality to self-assembling peptide nanofibers is challenging since such additions can inhib

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

159 feasibility of incorporating lignocellulosic nanofibers (LCNF) to paper in order to maintain the rele

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

161 ferent corona-forming block to the resulting nanofibers led to the formation of segmented B-A-B tribl

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

163 ts highlight the significance of electrospun nanofiber mats as smart surfaces to capture diverse clas

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

165 e efforts must increase the strength of TiO2 nanofiber mats to realize such applications.

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

167 In addition, nanofiber-mediated delivery of miR-219 and miR-338 promo

168 Therefore, in this study, we developed a nanofiber-mediated microRNA (miR) delivery method to con

169 Optimized TiO2 nanofibers meet or exceed the performance of traditional

170 However, the stable performance of the nanofiber membranes in the MD process is still unsatisfa

171 o the membranes fabricated by other methods, nanofiber membranes produced by electrospinning are of g

172 tegy to construct superhydrophobic composite nanofiber membranes with robust superhydrophobicity and

173 s is achieved by electrospinning a copolymer nanofiber mesh (NFM) directly onto a solid-state nanopor

174 ly and reproducibly printed onto electrospun nanofiber meshes (the "paper") to generate various micro

175 Porous three-dimensional nanofiber meshes are electrospun from these copolymers w

176 Bioactive and antifouling nanofiber meshes outperform traditional streptavidin-coa

177 g capabilities and detection limits of these nanofiber meshes under both static conditions (26 h) and

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

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

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

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

182 to a stable 4-carboxyphenyl layer on carbon nanofiber-modified screen printed electrode.

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

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

185 Further, the nanofiber morphology enhances its mass activity remarkab

186 that this hybrid catalyst has bamboo-shaped nanofiber morphology.

187 The role of nanofiber/nanoparticle carriers is substantiated by the

188 ospraying process and the ensuing control of nanofiber/nanoparticle surface parameters.

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

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

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

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

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

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

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

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

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

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

199 Nanofibers of controlled diameter (30-210 nm), crystal s

200 n this work, we examine the formation of the nanofibers of D-peptides via enzymatic dephosphorylation

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

202 The support was tiered with layers of nanofibers of different diameters to better withstand hy

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

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

205 o deposit poly(epsilon-caprolactone)/gelatin nanofibers on the Al(2)O(3) nanoporous support membrane,

206 functional characteristics of self-assembled nanofibers on the molecular structure of their building

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

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

209 ment membrane materials onto type 1 collagen nanofibers only in a region adjacent to the endothelial

210 Over the past decade, the synthesis of nanofibers or nanoparticles via electrostatic spinning o

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

212 nct morphologies on the nanoscale, either as nanofibers or spherical micelles, based on the incorpora

213 Silicon nanofiber paper anodes offer a completely binder-free an

214 agnesiothermic reduction of electrospun SiO2 nanofiber paper produced by an in situ acid catalyzed po

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

216 on of platinum nanoparticle decorated carbon nanofibers (PtNp-CNF) in poly(diallyldimethylammonium) c

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

218 s establish periodic alignments between both nanofibers resulting in a material with alternately segr

219 on, we propose graphene-wrapped anatase TiO2 nanofibers (rGO@TiO2 NFs) through an effective wrapping

220 This FA-modified PCL nanofiber scaffold shows promising potential for future

221 d on a polyvinylidene fluoride (PVDF) porous nanofiber scaffold via electrospinning.

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

223 FA crystals within the three-dimensional PCL nanofiber scaffolds provided a favorable extracellular m

224 the FA crystals were synthesized on the PCL nanofiber scaffolds.

225 he hysteresis loop, addition of preassembled nanofiber seeds leads to seeded polymerization from the

226 Additionally, pH-sensitive nanofibers showed improved tumor accumulation over both

227 ellulose that combines a mechanically strong nanofiber skeleton with a lateral fibrillar diameter of

228 Electrospun polymer nanofiber stationary phases were examined for their appl

229 Peptides that adopted nanofiber structures displayed less hemolytic activity,

230 ylindrical geometry of the fibers and to low nanofiber substrate coverage, providing a less crowded e

231 ary of bioactive and antifouling electrospun nanofiber substrates, which are composed of high-molecul

232 Individual nanofibers successfully act as luminescent reporters of

233 EO processes due to its thin, highly porous nanofiber support layer.

234 These results indicate that hydrophilic nanofiber supported thin film composite membranes have t

235 This result shows the immense promise of nanofiber supported thin-film composite membranes for us

236 vance PRO by introducing a novel electrospun nanofiber-supported thin-film composite PRO membrane pla

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

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

239 phobic interior and immobilized water on the nanofiber surface.

240 cancies and nitrogen are introduced into the nanofibers surface.

241 acid functionalized copper doped zinc oxide nanofibers synthesized by electrospinning technique.

242 synthesis of GNRs using electrospun polymer nanofiber templates.

243 lapping filaments form buckles between their nanofiber tethers and myosin attachment points.

244 therefore provide the earliest report of MOF-nanofiber textile composites capable of ultra-fast degra

245 ccumulation over both spherical micelles and nanofibers that did not change morphologies in acidic en

246 ation of enzyme entrapped-conducting polymer nanofibers that offer higher sensitivity and increased l

247 The origins of apatite nanofibers, the development of a stiffness gradient, and

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

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

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

251 elf-assembles into elongated one-dimensional nanofibers through a cooperative nucleation-growth proce

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

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

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

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

256 polyvinylidenefluoride (PVDF) piezoelectric nanofiber tip links.

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

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

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

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

261 As compared to two-dimensional culture, nanofiber topography enhanced OPC differentiation by ind

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

263 arations were performed on polyacrylonitrile nanofiber ultra-thin-layer chromatography (UTLC) plates

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

265 ydrate amphiphile able to self-assemble into nanofibers upon enzymatic dephosphorylation.

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

267 s) fabricated with vertically aligned carbon nanofibers (VACNFs).

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 However, the practical value of Au/TiO2 nanofibers was limited by their greater degree of inhibi

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

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

273 Vertically aligned carbon nanofibers were grown using plasma enhanced chemical vap

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

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

276 Palladium-incorporated poly(4-vinylphenol) nanofibers were prepared by electrospinning with control

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

278 Nanofibers were shown to behave similarly to conventiona

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

280 hiral MoS(2) and multiwalled carbon nanotube nanofibers were used as promising active layers for flex

281 SA, bovine serum albumin), coated on Nylon-6 nanofibers were used for these measurements.

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

283 ds, the nucleopeptides self-assemble to form nanofibers, which results in supramolecular hydrogels up

284 thesize diamond by converting "solid" carbon nanofibers with a Spark Plasma Sintering system under lo

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

286 Electrospun nanofibers with controllable degrees of crimping are fab

287 the average Young's modulus of polyethylene nanofibers with diameters from 70 nm to 260 nm can be as

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

289 0-50 nm) were developed along with composite nanofibers with either surface-deposited or bulk-integra

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

291 n electrospun polycaprolactone (PCL) NanoECM nanofibers with or without the FA crystals.

292 elucidate the interactions of the molecular nanofibers with other molecules, thus facilitating the d

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 Titanium dioxide (TiO2) nanofibers with tailored structure and composition were

296 attery electrodes, we further prepare carbon nanofibers with tin-doped indium oxide nanoparticles dec

297 nucleate and grow directly on and around the nanofibers, with strong attachment to the substrates.

298 s the nine methylene CAs assembled into long nanofibers without crystalline molecular packing.

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