ライフサイエンスコーパス: nanostructure

1 (V) (2)O(40))(C(6)H(12)N(2)O(4)S(2))(4)](5-) nanostructure.

2 hanical properties of a DNA origami triangle nanostructure.

3 to design and analysis of a range of DNA/RNA nanostructures.

4 fly scale laminae, which are simple photonic nanostructures.

5 pathways to improve the self-assembly of DNA nanostructures.

6 h is paying much attention to heterojunction nanostructures.

7 ed one-dimensional arrangement of nucleobase nanostructures.

8 e rational design of functional hierarchical nanostructures.

9 superconducting transition temperature of Sn nanostructures.

10 n of fully engineered three-dimensional (3D) nanostructures.

11 many combinations resulted in distinct lipid nanostructures.

12 ular architecture and previously reported 2D nanostructures.

13 d not solvent oxidation products) to form Ag nanostructures.

14 e glycol block copolymers into 1D, 2D and 3D nanostructures.

15 , which constrain the practical use of these nanostructures.

16 ystem for the predictable synthesis of metal nanostructures.

17 ation or fluorescent imaging adjacent to the nanostructures.

18 surface and electronic modifications of the nanostructures.

19 atform for preparing next-generation complex nanostructures.

20 roduction of these highly ordered multigrain nanostructures.

21 ir programmable organization in hierarchical nanostructures.

22 lity for fabricating both static and dynamic nanostructures.

23 lating the morphology evolution of plasmonic nanostructures.

24 using programmable stimuli-responsive micro/nanostructures.

25 rushes to form well-defined, one-dimensional nanostructures.

26 eation of new and the import of existing DNA nanostructures.

27 echnology to control the assembly process of nanostructures.

28 a general route towards designing versatile nanostructures.

29 or the design, modelling and analysis of DNA nanostructures.

30 hly water-repellent and mechanically fragile nanostructures.

31 he electron-tunneling width between graphene nanostructures (~ 38 nm) by only 0.19 A reduces the elec

32 shape, compactness and stiffness of the DNA nanostructure affect both internalization into plant cel

33 We provide evidence that composite nanostructures allow for surface photovoltages to be cre

34 n studied as a versatile route to synthesize nanostructured alloys.

35 These nanostructures also serve as anticaking agents, nano-add

36 Here, the roles of the grain-interior nanostructure and the grain boundaries in controlling co

37 progress in the development of novel carbon nanostructures and carbon-derived energy storage devices

38 hmark and optimize pPAINT using designer DNA nanostructures and demonstrate its cellular applicabilit

39 tonishing pace, de novo design of complex 3D nanostructures and functional devices remains a laboriou

40 to more complex synthetic nucleic acid-based nanostructures and functionalized smart materials.

41 Peptide-based biomimetic nanostructures and metal-organic coordination networks o

42 Diverse scale nanostructures and non-uniform cuticle thicknesses creat

43 oscopy (AFM) to characterize the DNA origami nanostructures and structured illumination microscopy (S

44 for crystal growth/synthesis of these unique nanostructures and their potential technological applica

45 on with the same photon count on DNA-origami nanostructures and tubulin in cells, using DNA-PAINT and

46 rrelations among the nature of active sites, nanostructures, and catalytic activity of M-N-C catalyst

47 among the best values for NiCo(2)O(4)-based nanostructures, and even better than those for IrO(2) an

48 RNA nanotechnology, multivalent nucleic acid nanostructures, and nucleic acid aptamers, which, respec

49 ced dynamical processes in atoms, molecules, nanostructures, and solids.

50 Furthermore, the nanostructure annotation procedure generates 2142 nanode

51 ence of increased nucleic acid content, this nanostructure architecture exhibits less cell cytotoxici

52 All the nanostructures are annotated and transformed into protei

53 Such porous Au@Rh core-shell nanostructures are expected to exhibit catalase-like act

54 ructural and functional properties of carbon nanostructures are highly beneficial for healthcare diag

55 Copper nanostructures are promising catalysts for the electroch

56 ries, and properties found in chiral ceramic nanostructures are summarized.

57 strate the specificity and efficiency of the nanostructure as a drug delivery vehicle.

58 Here, we use a custom-designed DNA origami nanostructure as a model system to specifically mimic a

59 e possibility to combine and re-use existing nanostructures as building blocks for the creation of ne

60 ecent advancements in preparation methods of nanostructures as food additives and packaging stuffs al

61 s obtained confirm the performance of ZOL-GO nanostructures as promising drug complexes for the treat

62 block copolymers self-assemble into compact nanostructures, as illustrated by their reduced domain s

63 We find that nanostructures assembled from DNA brick motifs remain st

64 rface Raman scattering enhancement on chiral nanostructured Au films (CNAFs) equipped in the normal R

65 uch as perovskite solar cells, organic-, and nanostructure-based photovoltaics.

66 A low-cost metallic nanostructure-based surface plasmon resonance (SPR) imag

67 que DNA handles in order to link DNA origami nanostructures bearing complementary strands into microm

68 particles can be deliberately used to access nanostructures beyond what is possible with DNA hybridiz

69 Customizable nanostructures built through the DNA-origami technique h

70 nced biostability can be engineered into DNA nanostructures by adopting PX-based architectures or by

71 The fabrication of Ru nanostructures by focused electron beam induced depositi

72 gy, measuring their rapid dynamics on single nanostructures by X-rays, electron beams, or tunnelling

73 monic noble metals, and thus our oxide-based nanostructures can be considered as quasi-metallic.

74 Our demonstration, that composite nanostructures can be designed to take advantage of opti

75 Experimentally, chiral properties of nanostructures can be either created artificially using

76 In addition, the nanostructures can be modified and analysed on-the-fly u

77 We further discuss how such DNA nanostructures can be rationally designed to efficiently

78 calized surface plasmon resonances (LSPR) of nanostructures can be tuned by controlling their morphol

79 We have demonstrated that DNA nanostructures can be utilized as a cargo carrier for di

80 ZOL-GO nanostructures can facilitate the mineralization of BM-M

81 Plasmonic nanostructures can focus light far below the diffraction

82 igned using three DNA triangular prism (DTP) nanostructures carrying two pairs of metastable catalyti

83 ng from molecular systems to single-atom and nanostructured catalysts.

84 ystals outperform those of commercial Pt and nanostructured catalysts.

85 re adjacent catalytic interfaces in a single nanostructure catalyze sequential reactions, we describe

86 mature plants, and provide guidance for DNA nanostructure characterization, storage and use.

87 cular-plasmonic assemblies, chiral plasmonic nanostructures, chiral assemblies of interacting plasmon

88 norods (NRs), with varying content of carbon nanostructures (CNs=MWCNTs and RGO), are prepared using

89 -dimensional, porous electrode materials and nanostructured coatings are forging a path toward more s

90 Nanostructured coatings made with chitosan (100%Q), algi

91 id crystalline phase, leading to solid-state nanostructured colored films upon solvent evaporation, e

92 ee (i.e., LSPR-free), topologically tailored nanostructure composed of porous carbon nanowires in an

93 A data model supporting different DNA nanostructure concepts (multilayer DNA origami, wirefram

94 tallization process generates biomineralized nanostructures consisting of 2.5-nm crystalline particle

95 to find out whether a myriad of novel lipid nanostructures could be obtained.

96 ide-based building units into supramolecular nanostructures creates an important class of biomaterial

97 urity and polycrystalline nature, the MoS(2) nanostructures demonstrate rapid optoelectronic response

98 Nanostructure design and in situ transmission electron m

99 faces at two different length scales, with a nanostructure design to provide water repellency and a m

100 rnet solid electrolytes/electrodes, emerging nanostructure designs, degradation mechanisms and mitiga

101 ncluding, analyte, aptamer sequence, type of nanostructure, diagnostic technique, analyte detection r

102 the construction of heterophase noble metal nanostructures difficult.

103 DNA nanostructures (DNs) have garnered a large amount of int

104 A nanostructured electrochemical DNA-based biosensor was p

105 ion was acquired by employing high-curvature nanostructured electrodes for sensitive sample analysis

106 asing the effective surface area via thicker nanostructured electrodes hinders the analyte's permeati

107 as well as other substrates for binder-free nanostructured electrodes in LIBs are summarized systema

108 potential applications of these binder-free nanostructured electrodes in practical full-cell-configu

109 Thus, nanostructured electrodes with binder-free designs are d

110 these were also turned to continuous film of nanostructures eliminating all interparticle gaps on the

111 fference of the (13)C NMR signals of the two nanostructured enantiomers vanished.

112 multiple classes of molecules into a single nanostructure, enhancing active targeting of therapeutic

113 rmation of various dimensions of phosphorene nanostructures, especially zigzag-phosphorene nanobelts.

114 ork is to provide optimized formulations for nanostructured etoposide solutions and validate by means

115 AuNP clusters, this novel designed 3D radial nanostructure exhibits an ultrasensitive detection of DN

116 This nanostructure exhibits the intrinsic activity in selecti

117 lly synthesized TiO(2)@MoS(2) heterojunction nanostructure for the effective production of photoinduc

118 , antimony naturally evolves to form optimal nanostructures for alloy anodes, as we show through elec

119 ometers in width, are among the most studied nanostructures for biomedical applications.

120 d the synthesis of semiconductors as well as nanostructures for energy storage applications.

121 ectively steer energy pathways in functional nanostructures for optoelectronics.

122 imized structure of the CdSe QD-peptide-AuNP nanostructures for the application.

123 ment to generate geometrically optimized DNA nanostructures for transgene-free and force-independent

124 This new approach mediated by core/shell nanostructure formation and conversion can be extended t

125 ally, the morphologies of the self-assembled nanostructures from block copolymers are limited to sphe

126 s the conceptual assembly of ionic inorganic nanostructures from monolayers without the requirement o

127 We report the use of DNA origami nanostructures, functionalized with aptamers, as a vehic

128 The incorporation of Cu(2+) into BP@Cu nanostructures further enables chemodynamic therapy (CDT

129 agnetic, and biological properties of chiral nanostructures, further stimulating theoretical, synthet

130 Here, recent developments and challenges for nanostructured gel-based materials for electrocatalysis

131 Hot carriers in plasmonic nanostructures, generated via plasmon decay, play key ro

132 anti-PSA, are immobilized onto two adjacent nanostructured gold electrodes.

133 R) properties of chemically synthesized gold nanostructures, gold triangular nanoprisms (Au TNPs), go

134 surface morphology and shape of crystalline nanostructures governs the functionality of various mate

135 impact of eco-toxicity due to application of nanostructures has also been discussed based on recent o

136 However, predictively synthesizing nanostructures has been difficult to achieve using conve

137 r information coding (MIC) on those designed nanostructures has gained increasing attention for infor

138 Light-driven synthesis of plasmonic metal nanostructures has garnered broad scientific interests.

139 ed hot holes in regulating the morphology of nanostructures has not been fully explored.

140 the ability to tune surface and interface of nanostructures has provided a versatile tool for the dev

141 structures toward more structurally complex nanostructures has revolutionized live-cell analysis.

142 tate energy distributions of hot carriers in nanostructures has so far been lacking.

143 , aptasensors with the applying of different nanostructures have been able to provide new windows for

144 Through judicious design, disordered nanostructures have been realised in artificial systems,

145 Hollow and yolk-shell nanostructures have been used to increase the cycling st

146 ative concepts realized in motile micro- and nanostructures have converged in the field of small-scal

147 Three-dimensional (3D) subwavelength nanostructures have emerged and triggered tremendous exc

148 Materials patterned with high-aspect-ratio nanostructures have features on similar length scales to

149 All-dielectric nanostructures have recently opened exciting opportuniti

150 DNA nanostructures have shown potential in cancer therapy.

151 embly into crystalline frameworks or uniform nanostructured hydrogels of spherical, vesicular, or cyl

152 scalable fabrication of longitudinal MoS(2) nanostructures, i.e., nanoribbons, and their oxide hybri

153 The nanostructures improve the solubility of food ingredient

154 onstrate that a six-helix bundle DNA origami nanostructure in the submicrometre scale (meta-DNA) coul

155 s used to simultaneously irradiate plasmonic nanostructures in a (scanning) transmission electron mic

156 novel software tool for the modelling of DNA nanostructures in a user-friendly environment.

157 nducting transition temperature (T(C)) of Sn nanostructures in comparison to bulk, was studied.

158 ions given the utility of DNA-functionalized nanostructures in diagnostics and therapeutics.

159 d for guaranteed structural stability of DNA nanostructures in physiological conditions.

160 electron microscopy contrast of carbonaceous nanostructures in respect to ceramic background, the min

161 enable formation of complex, self-assembling nanostructures in select polar aprotic organic solvent m

162 hlighted the application of various types of nanostructures in the food industry.

163 processes leading eventually to carbonaceous nanostructures in the interstellar medium and in combust

164 eld element-specific morphology of embedding nanostructures in ultrathin films.

165 replacement can produce inverse FeO(x)/metal nanostructures in which the concentration of oxide speci

166 adband and wide-angle antireflective surface nanostructuring in GaAs semiconductors using variable do

167 A series of positively charged plasmonic nanostructures including gold/silver nanospheres, nanosh

168 Here, we develop hybrid nanostructures incorporating both refractive and plasmon

169 incremental increase of nanopillar height on nanostructure-induced bacterial cell death.

170 ehaviors, predominantly focusing on the cell-nanostructure interface.

171 Inspired by the nanostructured interfaces between tendons/ligaments/cart

172 Metasurfaces are engineered nanostructured interfaces that extend the photonic behav

173 ensor fabrication methods, the materials and nanostructures involved, the detection principles and th

174 molecular organization of heteromultivalent nanostructures is critical for effective binding; patter

175 Enhancement of optical emission on plasmonic nanostructures is intrinsically limited by the distance

176 The development of applications for chiral nanostructures is rising rapidly.

177 ed conjugated polymers which are confined in nanostructures is utilized.

178 g probe capable of elucidating the real-time nanostructure kinetics with unprecedented resolutions.

179 embly of biomacromolecules into well-defined nanostructures, leveraging pathway complexity of molecul

180 anic frameworks do not have a well-developed nanostructure library, and establishing their appropriat

181 h an electrochemical sensor modified with Au nanostructures, LiClO(4) -doped conductive polymer, and

182 osome, solid-lipid nanoparticles (SLNs), and nanostructured lipid carriers (NLCs)), etc.

183 aluated as surfactants for the production of nanostructured lipid carriers (NLCs).

184 ulate systems (solid lipid nanoparticles and nanostructured lipid carriers), liposome entrapment, nan

185 ic objects separated by nanogaps, or between nanostructures located in the far-field of each other, c

186 possibilities for creating chiral plasmonic nanostructures, luminescent biological labels, and nanos

187 The resulting nanostructures (Lys-SNAs) enhance the codelivery of adju

188 Nanostructured magnetic materials provide an efficient t

189 e oxide (GO) is conjugated with ZOL, and the nanostructured material is evaluated in terms viability,

190 he art of emerging chiral liquid crystalline nanostructured materials and their technological applica

191 A clear need exists for novel nanostructured materials that are capable to meet the pe

192 Here, we apply the proposed method to design nanostructured materials to maximize elastic properties.

193 niques enables the generation of macroscopic nanostructured materials with potential applications in

194 ly determine the atomic structure of complex nanostructured materials.

195 thermic combustion of mechanically-activated nanostructured metallic precursors in nitrogen and conso

196 ted strands are captured at the surface of a nanostructured microelectrode.

197 ta, which spearheads a new generation of DNA nanostructure modelling software.

198 -design principle for creating double-gyroid nanostructured molecular assemblies based on atropisomer

199 We further demonstrate nanostructure morphology can be tuned by means of solven

200 hat possess good electrochemical properties, nanostructured morphology and functionality for bioconju

201 The nanostructured morphology, chemical characteristics and

202 -toxicity, good environmental stability, and nanostructured morphology.

203 controlling the out-of-equilibrium state of nanostructured Mott insulators hold great promises for e

204 Here, we demonstrate that nanostructured, multilayer transition metal dichalcogeni

205 ransistor (DGTFT) as the actuator and an MZO nanostructure (MZO(nano)) array coated conducting pad as

206 orted for the construction of a 3D honeycomb nanostructured, N,P-doped carbon aerogel incorporating i

207 ts enable the generation of 2D self-charging nanostructured networks on a large scale.

208 ing, to self-assemble two-dimensional carbon nanostructured networks on a large scale.

209 The macro-sized (meter-level) carbon nanostructured networks show extraordinary nanostructura

210 Here we report that nanostructured NiFe oxide (NiFeO(x)) and nitride (NiFeN(

211 ron tomography, we explore the 3-dimensional nanostructure of TT in rabbit ventricular myocytes, pres

212 on the role of the support on directing the nanostructures of Au-based monometallic and bimetallic n

213 Contrary to previous studies, HCP phase in nanostructures of gold was stabilized and did not transf

214 Both one- and two-dimensional nanostructures of lithium nitride, Li(3)N, can be grown

215 ioprobe translated from GO-Ru(II) conjugated nanostructures offers new insights for further studies i

216 n donor, as well as core/shell SnO(2)/TiO(2) nanostructures, often prolong the lifetime of the inject

217 Controlling self-assembled nanostructures on bulk insulators at room temperature is

218 the two peptides to TiO(2) surfaces (either nanostructured or single-crystal TiO(2)(110)) was found

219 Gold nanostructures or their hybrids with other metals are po

220 It can form nanostructures over the millimeter-scale by simply spinn

221 One-dimensional (1D) nanostructured oxides are proposed as excellent electron

222 near-infrared-fluorescence amplification by nanostructured plasmonic gold substrates, for the simult

223 Nanostructured plasmonic materials can lead to the extre

224 i-tumor efficacy revealed that certain lipid nanostructures possessed superior tumor retardation effe

225 Nanozymes or enzyme mimetic nanostructures possessing intrinsic catalytic activity c

226 We envision that nanostructures presenting spatially patterned heteromult

227 The nanostructures provide enhanced sensitivity, while PCR o

228 While the advent of nanostructuring provided a general design paradigm for r

229 emonstrate for the first time that composite nanostructures providing nonlocal environments can be en

230 graphy and cryptography synchronously on DNA nanostructures remains a challenge.

231 the synthesis of two-dimensional (2D) silica nanostructures remains challenging.

232 However, the nanostructures reported on up to date usually utilize a

233 The PDOS of all nanostructured samples shows a slightly increased number

234 Among various smart-electro-active nanostructures sensing materials, liquid crystals (LCs)

235 le method based on a novel electroanalytical nanostructured sensor has been developed to perform quan

236 The ability to control nanostructure shape and dimensions presents opportunitie

237 unique structural and optical properties of nanostructured Si(2)Te(3) hold great potential applicati

238 ral parameters to characterize large DNA/RNA nanostructures simulated using the coarse-grained modeli

239 hardness of diamond can be increased through nanostructuring strategies(1,2), among which the formati

240 Nanostructured substrates offer a unique solution to add

241 ure/release, multimarker antibody cocktails, nanostructured substrates, and microfluidic chaotic mixe

242 e nanomaterial database containing annotated nanostructures suited for modeling research.

243 ited by the distance between the emitter and nanostructure surface, owing to a tightly-confined and e

244 An optimized nanostructured surface shows a reduced surface reflectiv

245 rward approach by combining active plasmonic nanostructures, surface-enhanced Raman spectroscopy (SER

246 hysico-mechanical interactions between these nanostructured surfaces and bacteria lead to bacterial k

247 This review considers how high-aspect-ratio nanostructured surfaces are used to both stimulate and s

248 The mechano-bactericidal activity of nanostructured surfaces has become the focus of intensiv

249 od based on molecular dynamics simulation of nanostructured surfaces providing in silico predictions,

250 The development of new antibacterial nanostructured surfaces shows excellent prospects for ap

251 Here, we report a vivid self-assembled nanostructured system which overcomes these challenges v

252 ineer and customise these ingenious coloured nanostructures tackling the current performance of organ

253 ires a higher energy to fracture the ordered nanostructures than amorphous polymer chains.

254 Here we demonstrate a designer DNA nanostructure that can act as a template to display mult

255 d space can have a significant impact on the nanostructure that hosts it.

256 strate that other butterflies employ simpler nanostructures that achieve ultra-black coloration in sc

257 Stimuli-responsive micro/nanostructures that can dynamically and reversibly adapt

258 atile approach to prepare novel carbon-based nanostructures that cannot be obtained by conventional s

259 In diverse organisms, nanostructures that coherently scatter light create stru

260 materials, but few examples exist of hybrid nanostructures that contain both components.

261 DNA nanopores are bio-inspired nanostructures that control molecular transport across l

262 ld rely on optical antenna theory, involving nanostructures that locally convert propagating waves in

263 oated with an ensemble of metallic plasmonic nanostructures that only transmits light incident along

264 vely charged Avidin grafted branched Dextran nanostructures that utilize long-range binding effects o

265 Nanostructuring the working electrode enhances sensor pe

266 ndo techniques, we show that in the emergent nanostructure, the endogenous nanoparticles and the pero

267 rt behaviours in various crystalline silicon nanostructures, the corresponding characteristics of amo

268 mble of conformations adopted by dynamic DNA nanostructures, the equilibrium structure and dynamics o

269 we will discuss the influence of the polymer nanostructure (thin or grafted layers, polymer ordering,

270 by re-using a large nanorod to create a new nanostructure through user interactions that employ diff

271 photothermal therapy and rationally designed nanostructures to circumvent cancer immunotherapy failur

272 comes from the ability of high-aspect-ratio nanostructures to deliver cargoes into cells and tissues

273 int toward accelerated optimization of C-S-H nanostructures to design efficient cementitious binders

274 Nonlinear nanophotonics leverages engineered nanostructures to funnel light into small volumes and in

275 Se(2), 1T'-MoTe(2) and T(d)-WTe(2) few-layer nanostructures to produce several distinct classes of 0D

276 However, the interaction of light with such nanostructures typically loses all information about the

277 Controlled synthesis of nanostructure ultrathin films is critical for applicatio

278 lacement reactions for realizing dynamic DNA nanostructures, variants on the basic motif have not bee

279 tigated the formulation of novel lipid-based nanostructures via simple tuning of lipid combinations.

280 es hinders the analyte's permeation into the nanostructured volume and limits its access to deeper el

281 disulfide/graphene (MoS(2)/graphene) hybrid nanostructure was proposed and fabricated for DNA hybrid

282 By changing the shape of nanostructures, we are able to vary the surface plasmon

283 Nanostructures - which are formed inside the microstruct

284 ically require the complete encapsulation of nanostructures, which makes accessing the encased DNA st

285 DNA, when folded into nanostructures with a specific shape, is capable of spac

286 of bovine serum albumin (BSA) to form stable nanostructures with bioactive molecules.

287 ns were only observed with polyhedron shaped nanostructures with certain compositions and not with tr

288 ffers a feasible pathway to combine quasi-3D nanostructures with colloidal materials-based optoelectr

289 method involving the synthesis of DNA brick nanostructures with dendritic oligonucleotides attached

290 nsely coating the outer surface of DNA brick nanostructures with dendritic oligonucleotides prevents

291 of nanometers, albeit for planar samples or nanostructures with moderate height variations.

292 nction relationship for non-noble bimetallic nanostructures with multifunctional electrocatalytic pro

293 ttom-up' method to create 3D superconducting nanostructures with prescribed multiscale organization u

294 DNA nanostructures with programmable nanoscale patterns has

295 ) blocks that can self-assemble into ordered nanostructures with sub-1 nm domains and full domain pit

296 Coating Au@Rh nanostructures with tumor cell membrane (CM) enables tum

297 espectively, provide the ability to engineer nanostructures with unparalleled levels of structural co

298 ution to this problem by driving accelerator nanostructures with visible or near-infrared pulsed lase

299 to enable a month-long retention of cationic nanostructures within the NP following intra-discal admi

300 Nanostructured ZOL-GO with an optimum performance is syn