ライフサイエンスコーパス: nano-

1 f techniques used to pattern polymers on the nano (1-100 nm) and submicrometre (100-1,000 nm) scale,

2 scales, from the molecular (1-100 A) via the nano (10-100 nm) to the meso (1-100 microm).

3 In this study, nano (20 nm) and micron (0.3 and 0.6 um) size MgO partic

4 Budesonide-PLA nano- (345 nm) and microparticles (3.6 microm), with an

5 engineer hierarchical structures with meso-, nano- and atomic architectures that give the final compo

6 Atom-probe tomography (APT) facilitates nano- and atomic-scale characterization and analysis of

7 iven NP movement may benefit a wide range of nano- and bio-applications and provide new insights to t

8 neficial in expanding the scope of DNA-based nano- and biotechnologies.

9 ed substrate specificity for applications in nano- and biotechnology and in the enzymatic synthesis o

10 Formulating effective coatings for use in nano- and biotechnology poses considerable technical cha

11 cted inorganic compounds for applications in nano- and biotechnology.

12 After 36 days of exposure to 1000 mg/kg nano- and bulk-CeO2, roots accumulated 26 and 19 mug/g C

13 hazard evaluation framework, which combines nano- and bulk-material properties into a hazard score,

14 However, the occurrence of nano- and larger sized particles of Ag and CeO(2) was ob

15 ent of distribution and anti-tumor effect of nano- and macromolecular systems.

16 fective underwater adhesives with adjustable nano- and macroscale characteristics requires an intimat

17 mical functionality that is tuned across the nano- and macroscales.

18 tical tool to examine ballistic transport in nano- and meso-scale junctions, but it necessitates that

19 ly affected by processing-induced changes in nano- and meso-scale structure in PEDOT: PSS films.

20 mized two-dimensional (2D) geometries at the nano- and meso-scale.

21 an be programmed to self-assemble into novel nano- and meso-scopic architectures of desired size and

22 tion of structural materials, fatigue at the nano- and mesoscale has been marginally explored or unde

23 nique to study the structure and dynamics of nano- and mesoscale objects.

24 nsforms into zeolite nanosheets with uniform nano- and mesoscale porosities.

25 formation of heterogeneous distributions of nano- and mesoscale pre-percolation clusters in sub-satu

26 xygen within TPI-carbon nanoparticles at the nano- and mesoscale ranges has been demonstrated.

27 nvestigates magnetic ordering temperature in nano- and mesoscale structural features in an iron arsen

28 s approach can be generalized to study other nano- and mesoscale structures.

29 chalcogenide solids, with pore sizes in the nano- and mesoscale, are of potentially broad technologi

30 allows for unprecedented manipulation at the nano- and mesoscales, which has the potential to provide

31 d polyelectrolytes modulate ion transport on nano- and mesoscales.

32 Nano- and mesostructuring is widely used in thermoelectr

33 PVDF and P(VDF-TrFE) nano- and micro- structures have been widely used due to

34 We correlate physical nano- and micro- structures to the helium ion dose, as w

35 o the development of spectacular luminescent nano- and micro-architectures, through a combination of

36 nhanced mass and charge transfer imparted by nano- and micro-confinement effects within the porous me

37 Here we report the synthesis of nano- and micro-crystalline diamond-structured carbon, w

38 nhance energy dissipation through controlled nano- and micro-fracture, where the defects' size, geome

39 supramolecular order expressed at molecular, nano- and micro-levels is dramatically enhanced, and, im

40 r the use of bioadhesive polymers to enhance nano- and micro-particle uptake from the small intestine

41 of the flexibility of the apatite structure, nano- and micro-particles of hydroxyapatite (HAp) were d

42 e metal-organic framework (MOF) materials in nano- and micro-particulate, thin-film form.

43 eterogeneous mineralogy and poorly connected nano- and micro-pore systems.

44 find applications in drug and gene delivery, nano- and micro-reactors, substrates for macromolecular

45 ult of favorable percolation networks on the nano- and micro-scale and the plasticizing effect of the

46 These nano- and micro-scale cracks are further confined by lar

47 ill offer much potential for the creation of nano- and micro-scale DNA biosensor devices in silicon.

48 sive measurement for the characterization of nano- and micro-scale particles in dispersion.

49 f-assembly of molecular building blocks into nano- and micro-scale supramolecular architectures has o

50 precisely fabricate particles across and the nano- and micro-scale with defined shapes and compositio

51 ectrochemical biosensors and newly developed nano- and micro-scaled and aptamers based biosensors for

52 focuses on rare-earth carbonate materials of nano- and micro-size.

53 Our results showed that both nano- and micro-sized particles decorated with CD200 dec

54 acid (RNA) from three size fractions (pico-, nano- and micro/mesoplankton), as well as from dissolved

55 Functional and versatile nano- and microassemblies formed by biological molecules

56 l particles for the assembly of the shell of nano- and microcapsules holds great promise for the tail

57 ies and the progress made so far of bringing nano- and microcapsules with shells of densely packed co

58 can be used for the efficient production of nano- and microcarriers for various applications.

59 strate that by intelligently exploiting both nano- and microchemical architectures and wiring up the

60 effects on the mechanical behavior of ZIF-8 nano- and microcrystals were also investigated.

61 es a unique platform for introducing dynamic nano- and microdroplets into cells and organisms.

62 Here, we evaluated approach curves of nano- and microelectrodes to soft surfaces using SECM fo

63 very guides simultaneous control of both the nano- and microfeatures of the microspheres.

64 G, M, and Z) from river waters using polymer nano- and microfibers followed by HPLC with spectrophoto

65 Reactive spinning of nano- and microfibers that involves very fast chemical r

66 dal structures and to transport particles in nano- and microfluidic devices and displays.

67 can be harnessed for "on demand" pumping in nano- and microfluidic devices powered by an intrinsic e

68 he use of rare earth tungstate and molybdate nano- and micromaterials as single materials for the gen

69 nd clearance of two environmentally-relevant nano- and micromaterials by a model aquatic microoragani

70 omic arrangement of different polymorphs, to nano- and micrometer crystal dimensions, up to meter siz

71 [We denote particles on the nano- and micrometer scale as particulate matter (PM).]

72 Nano- and micrometer-scale crystals of a self-assembled

73 Particles formed with this combination of nano- and micrometer-scale dimensions possess a greater

74 allization) was used to prepare a mixture of nano- and micrometer-sized crystals of the monoclinic fo

75 The nano- and micrometer-sized crystals yielded a powder whi

76 singly used for guiding the self-assembly of nano- and micrometer-sized particles into larger scale o

77 The rational design of nano- and micrometer-sized particles with tailor-made op

78 ons that collectively span nearly the entire nano- and micrometre scale.

79 on function associated with their locomotion.Nano- and micromotors have been demonstrated in vitro fo

80 Distinguishing the operating mechanisms of nano- and micromotors powered by chemical gradients, i.e

81 fficiency of different classes of autonomous nano- and micromotors.

82 atively simple technology capable to produce nano- and micron-scale fibers with different properties

83 ree common approaches to collect and process nano- and micronscale information by STXM and the corres

84 producibility and spatial autocorrelation of nano- and micronscale protein, Fe(II) and Fe(III) densit

85 While nano- and microparticle-based imaging of cardiovascular

86 dy, model drug (vitamin D3, VD3)-loaded PLGA nano- and microparticles (NMP) were prepared by a single

87 Examples are luminescent nano- and microparticles and phosphors of different comp

88 spherical, rod-, and disk-shaped polystyrene nano- and microparticles and trastuzumab as the targetin

89 DL-Polylactide (PLA) nano- and microparticles containing budesonide were prep

90 of the current status of the application of nano- and microparticles in the imaging of cardiovascula

91 As the core of nanotechnology, nano- and microparticles offer "three-in-one" functions

92 unctival administration, both budesonide-PLA nano- and microparticles produced sustained budesonide l

93 Many applications of nano- and microparticles require molecular functionaliza

94 ubconjunctivally administered budesonide-PLA nano- and microparticles sustain retinal drug delivery.

95 er subconjunctivally administered budesonide nano- and microparticles sustain retinal drug levels.

96 I tract, we orally and rectally administered nano- and microparticles that we confirmed possessed sur

97 Budesonide-PLA nano- and microparticles were administered subconjunctiv

98 be used to predict bioadhesive properties of nano- and microparticles.

99 sponse for heterogeneous loads consisting of nano- and microparticles.

100 number of particle intermediates within the nano- and microparticles.

101 The nano- and micropatterned biosilica cell walls of diatoms

102 depend on the topographical features of the nano- and micropatterned surface.

103 Further, application of various nano- and micropatterning techniques allows for spatial

104 The amount of nano- and microplastic in the aquatic environment rises

105 thod was developed for the quantification of nano- and microplastics (NMPs) in water, sediments, and

106 Complementary modeling demonstrates nano- and microplastics have significantly distinct dist

107 c crystals, and fabricating light-controlled nano- and micropumps.

108 DNA origami manipulation and assembly at the nano- and microscale as well as other applications of th

109 phase separation of the ganglioside GM1 into nano- and microscale assemblies in a canonical lipid raf

110 , integration, and structural control on the nano- and microscale associated with the application of

111 ture, but ways to mimic the essence of these nano- and microscale dynamic molecular processes by nonc

112 and microbe spectroscopic information at the nano- and microscale in soil colloids.

113 ise for exceptional thermal transport across nano- and microscale interfaces under ideal conditions,

114 re, we review recent strategies that combine nano- and microscale materials and devices to produce la

115 ngth scale, curvature and confinement for 3D nano- and microscale membrane systems such as lipid drop

116 Data reveal nano- and microscale metallurgy-related, gilding-related

117 Nano- and microscale motors powered by catalytic reactio

118 over the past decade have demonstrated that nano- and microscale particles can be organized into a l

119 ermore, we demonstrate the ability to impart nano- and microscale patterning into such films through

120 eering linear assemblies with highly ordered nano- and microscale periodic features.

121 c semiconductor nanowires are of interest in nano- and microscale photonic and electronic application

122 Non-mechanical nano- and microscale pumps that function without the aid

123 chanistic connection between peptide-induced nano- and microscale reversible collapse structures (sil

124 binding groups is increasingly used to steer nano- and microscale self-assembly processes, with compl

125 The bottom-up fabrication of nano- and microscale structures from primary building bl

126 P and increase of complexity of the produced nano- and microscale structures.

127 needed for the development of new autonomous nano- and microscale systems.

128 olume-atomic force microscopy, we found that nano- and microscale tendon elastic moduli increase nonl

129 erization of historical gilt silver threads, nano- and microscale textural, chemical, and structural

130 treatment residues (WTRs)], and engineered [nano- and microscale zero valent iron (ZVI)] amendments.

131 ively for their adhesive capabilities at the nano- and microscale, however, much less is known about

132 elemental characterization techniques in the nano- and microscale.

133 l a water-filled porous scaffold on both the nano- and microscale.

134 d a central challenge for engineering at the nano- and microscales [1, 2].

135 s of forming and patterning materials at the nano- and microscales are finding increased use as a med

136 earch on reaction-diffusion processes at the nano- and microscales that we find hold particular promi

137 harge transfer have focused primarily on the nano- and microscales.

138 ramolecular descriptions of phenomena at the nano- and microscales.

139 should be combined in smart architectures on nano- and microscales.

140 between geometry and physical properties of nano- and microscopic Mobius strip structures.

141 ble indications to design more efficient ECL nano- and microsized labels for ultrasensitive bioanalys

142 efficient high-surface-area solar cells with nano- and microstructured semiconductor absorbers.

143 The emergence of complex nano- and microstructures is of fundamental interest, an

144 embly of block copolymers into 1D, 2D and 3D nano- and microstructures is of great interest for a wid

145 macroscopic assemblies feature hierarchical nano- and microstructures that provide numerous routes f

146 logy and dimension-controlled growth of gold nano- and microstructures with a time resolution of 5 ms

147 Polyhedral nano- and microstructures with shapes of faceted needles

148 p self-assembly process for creating surface nano- and microstructures, has been extensively studied

149 ompositions at all scales, from molecules to nano- and microstructures.

150 ased on radiotracers and small molecules, MI nano- and microsystems, and MI in context with comprehen

151 ein, we report our results in integration of nano- and molecular catalysis via catalytic synthesis of

152 ent can improve the delivery and efficacy of nano- and molecular medicines.

153 nsic knob for manipulating the properties of nano- and optoelectronic devices and harvesting novel fu

154 he extreme confinement provided by plasmonic nano- and pico-cavities can sufficiently enhance optomec

155 Microscopic aqueous sample droplets of nano- and picoliter volumes were formed on the bottom of

156 At nano- and picomolar concentrations, the new tacrine-4-ox

157 ally controlled AA' graphite exhibits unique nano- and single-crystalline feature and shows quasi-lin

158 inorganic compounds which can be regarded as nano- and sub-nano sized molecular relatives of metal-do

159 e aerosols included a significant portion of nano- and submicron-sized particles, and these can be di

160 f-consistent model of tunneling current in a nano- and subnano-meter metal-insulator-metal plasmonic

161 unique insight into wetting phenomena at the nano- and subnanometer scale.

162 ive as effective ligands in the synthesis of nano- and subnanoscaled materials because of their multi

163 onal behavior of these degrees of freedom on nano- and subnanosecond time scales.

164 ental to heterogeneous catalysis in both the nano- and the macro-scale.

165 In a cross-sectional study nano- and tissue-level mechanics were compared across tr

166 ed THz lasers, with impact in fields such as nano- and ultrafast photonics and optical metrology.

167 bsorption measurements on the femto-, pico-, nano-, and microsecond time scales and are examined by m

168 ectroscopy measurements on the femto, pico-, nano-, and microsecond time scales and by multiwavelengt

169 tionalization and compatible with micro- and nano- bio-environment.

170 xamined the effects of exposure to silver in nano-, bulk-, and ionic forms on zebrafish embryos (Dani

171 anization on multiple scales, from macro- to nano-, but nanoscale control of cardiac function has not

172 al mediator of the interactions at the bio - nano -materials interface but is not well understood.

173 ein-rich structures that ranges from uniform nano-, meso- and microscale puncta (distinct protein dro

174 ressing structural control across molecular, nano-, meso-, and bulk regimes is the essential next ste

175 By using intermediate nano-, micro- and macroscale free-floating membrane syst

176 icant work on their immediate environment at nano-, micro- and macroscopic levels.

177 terial synthesis and characterization at the nano-, micro- and mesoscales to random library screening

178 ophisticated 2D, 3D, and 4D materials at the nano-, micro-, and macrosize scales.

179 tural complexity which must be engineered at nano-, micro-, and mesostructural scales to enable organ

180 now have thousands of studies focused on the nano-, micro-, and whole-animal mechanics of gecko adhes

181 materials as precursors for the synthesis of nano-/micro-sized oxides, and their application as sacri

182 lymeric delivery methods such as dendrimers, nano-/micro-spheres or implants can improve the delivery

183 Advances in nano-/microfabrication allow the fabrication of biomimet

184 ials architectures in the form of dielectric nano-/microinclusions embedded in stretchable matrices,

185 d biodegradable bilayer MN arrays containing nano - microparticles for targeted and sustained intrade

186 ghlight the properties and results of Ac-DEX nano-/microparticles as well as the use of the polymer i

187 The historical uses of nano-/microscale materials and imaging techniques in art

188 ing functionalities of semiconductors at the nano-/microscale.

189 Metals of hybrid nano-/microstructures are of broad technological and fun

190 n that photoelectrodes made of semiconductor nano-/microwire arrays can have better photoelectrochemi

191 wall nanotubes (MWNTs), and hyperfullerenes (nano-"onions") were synthesized by several techniques an

192 for producing high-quality spherical carbon nano-'onions' in large quantities without the use of vac

193 der helped to bond crystal surfaces and link nano- or mesoscale particles together.

194 However, these artificially nano- or micro-engineered lenses usually suffer high los

195 monstrated thus far, however, have relied on nano- or micro-fabricated artificial composite materials

196 incorporation of biocompatible polymers into nano- or micro-fibers that can be configured into device

197 pagation' of order from the molecular to the nano- or micro-scale level.

198 in an appropriate solvent self-assemble into nano- or micro-scale network structures resulting in the

199 on agglutination of aptamer coated magnetic nano- or microbeads.

200 uantum dots/wires, nanoparticles, nanowires, nano- or microbelts, few-layered nanosheets, nano- or mi

201 H(2)-0.1TiH(2) system is superior to undoped nano- or micrometer-scaled MgH(2) with respect to the hy

202 gy to modulate functionality and function of nano- or microparticle surfaces.

203 technique coupled with preconcentration onto nano- or microparticle-based traps prior to analysis for

204 cessibility, possibly due to the presence of nano- or microparticles of elemental Se.

205 s, revealing specific means to functionalize nano- or microparticles.

206 ials have so far not yet been fashioned into nano- or microparticles.

207 nano- or microbelts, few-layered nanosheets, nano- or microplates, thin films, single crystals, and p

208 fronts of the skeleton, within a low-density nano- or microporous layer varying in thickness from 7 t

209 chemo-mechano-chemical feedback loops on the nano- or microscale.

210 ometers to allow analysis of biomolecules at nano- or picomole quantities, reducing the required amou

211 and histometrically the efficacy of micro-, nano-, or mixed-composite of hydroxyapatite (HA) graft i

212 icient technique for manipulating micro- and nano- particles, including microorganisms.

213 rent characteristics in microscopic domains (nano-, pico- and femtoliter range) with respect to usual

214 chemistry and analysis in aqueous samples of nano-, pico-, and femtoliter in volume.

215 acteristics in microscopic solution volumes (nano-, pico-, and femtoliter range) compared to the usua

216 cally stable microscopic aqueous droplets of nano-, pico-, and femtoliter volumes were made and kept

217 we use covalent virtual screening to produce nano-/picomolar boronic acid inhibitors of the carboxyle

218 g of the fate and distribution of micro- and nano- plastics in the marine environment is limited by t

219 nt of the luminescence intensity at 645nm of nano [Sm-(TC)2](+) complex doped in sol-gel matrix by va

220 analogous to the use of optically triggered nano-"sonicators" deep inside the body for drug delivery

221 y to effectively design and fabricate micro-/nano- structured materials.

222 e growth of graphene into desired micro- and nano- structures with control over placement, orientatio

223 Results showed that spherical nano-, submicro- and microcapsules were obtained through

224 ctural transformations and the properties of nano-/submicro-crystals under pressure.

225 structed tandem dimer of its binding partner nano (tdnano) to build light-activatable versions of RTK

226 sed formulations utilize silk's well-defined nano- through microscale structural hierarchy, stimuli-r

227 dynamics of CAP-Gly on time scales spanning nano- through milliseconds reveals its unusually high mo

228 ives estimates of human exposure to dietary (nano-) TiO(2), and discusses the impact of the nanoscale

229 depend on their microstructure, which is the nano- to centimeter scale arrangement of phases and defe

230 edical devices including precisely patterned nano- to centimeter scale polyhedral containers, scaffol

231 chieve tight binding with K(i) values in the nano- to femtomolar range.

232 es for nicotinamide-dependent enzymes in the nano- to femtomole scale, in alternative enzymatic assay

233 ned 14 confirmed hits with activities in the nano- to low-micromolar range.

234 ical properties of graphene that ranges from nano- to macro- scales, while balancing the acquisition

235 The nano- to macro-scale map reveals the tissue's biological

236 egies to computationally model MNWs from the nano- to macroscale and suggest future work to capture d

237 ials with a specific emphasis on advances in nano- to macroscale control, static to dynamic functiona

238 er- and intracellular heterogeneity from the nano- to macroscale is captured and dimensionally preser

239 , achieved by the definition of gradients in nano- to macroscale order.

240 ique platform for performing high-throughput nano- to macroscale photochemistry with relevance to bio

241 on while bridging materials fabrication from nano- to macroscale remains a challenge.

242 ctional control across size regimes from the nano- to mesoscale represents a significant challenge.

243 ver ranges of length (that can vary from the nano- to mesoscale) and timescales to enable local energ

244 ations for systems of widths that range from nano- to micro- meters.

245 Ts with a full structural size spectrum from nano- to micro- to macro-scale by using a variety of in

246 oving MS interface performance for low-flow (nano- to micro-) electrosprays.

247 s new ways to achieve electrical contacts in nano- to micro-devices.

248 tian potentiometric response to MB(+) in the nano- to micro-molar range.

249 cterize electron and vibration dynamics with nano- to micro-second lifetimes.

250 ) powder as the only precursor, to fabricate nano- to micro-size few layer thick MoSe(2) deposits wit

251 ation of natural, engineered, and incidental nano- to micro-size particles are beneficial to assessin

252 ected reaction monitoring detection from low nano- to microgram per milliter levels.

253 These nano- to micrometer scale structures are formed predomin

254 nfirmed GA formed spherical particles in the nano- to micrometer size range, suggesting this mechanis

255 5-80 degrees C) indicated rapid formation of nano- to micrometer sized HA crystals on granular limest

256 re we provide a novel method of synthesizing nano- to micrometer sized HA on the surfaces of granular

257 The voltammetric response for nano- to micrometer-sized electrode arrays are represent

258 ipids become preserved after adsorption into nano- to micrometer-sized pores, but to this day the dis

259 In nature, nano- to micrometer-sized structured materials made from

260 coiled coils with affinities that range from nano- to micromolar [Cu(II)], and picomolar [Cu(I)].

261 ounds inhibited the KDM5 members in cells at nano- to micromolar levels and induce a global increase

262 oxide species formed during autoxidation of nano- to micromolar levels of NO were examined using the

263 anup and found to more completely remove the nano- to micromole amounts of anions (and cations) in HP

264 e/ZnS QDs and 5-20 nm Fe(3)O(4) MNPs, bridge nano- to micron length scales, and can be modulated in s

265 ultiscale helical assembly, progressing from nano- to micron scale helical structures as the solution

266 nfined metallic surfaces, we observe in situ nano- to microscale dissolution and pit formation (quali

267 vel assemblies have been obtained, including nano- to microscale fibers, gels, spheres, and meshes, e

268 entation, movement, and sense of rotation of nano- to microscale objects is currently an active resea

269 We investigate formation of nano- to microscale peptide fibers and sheets where asse

270 ics measurements at resolutions covering the nano- to microscale, enabling the charting of cellular h

271 hermoresponsive hydrogel particles, from the nano- to microscale, using a single starting material.

272 ntrolled self-assembly of three-dimensional, nano- to microscale-patterned inorganic materials.

273 areas with a range of feature sizes from the nano- to microscale.

274 bsorption fine structure spectroscopy at the nano- to microscale.

275 n demonstrated for (i) colloids ranging from nano- to microscale; in two field-based granular media o

276 NiP occurs efficiently in all systems on the nano- to microsecond time scale, through three distinct

277 direct residue-specific probes of motions on nano- to microsecond timescales.

278 behavior of these proteins on time scales of nano- to microseconds.

279 function of colloid size were examined using nano- to microsized (0.1-4.2 mum) carboxylate-modified p

280 designing self-assembling peptide fibrillar nano- to microstructures is described.

281 t glucose affinities (K(d)) covering the low nano- to mid- millimolar range can be targeted genetical

282 ast two ternary complex intermediates in the nano- to millisecond time scale (1000-10000 s-1) that eq

283 ain relative to the C-terminal domain on the nano- to millisecond time scale.

284 Here the authors present nano- to millisecond time-resolved X-ray scattering meas

285 Here, we use nano- to millisecond time-resolved X-ray scattering to v

286 f domain motions fall into the interval from nano- to milliseconds, amenable to NMR studies.

287 Nano- to picomolar 5, 6-epoxyeicosatrienoic acid induced

288 for radiopharmaceuticals is conducted at the nano- to picomole scale, conventional chemical character

289 he domain by dynamics of the backbone on the nano- to picosecond time-scale shown by (15)N relaxation

290 the semi-quantitative analysis of both fast (nano- to picosecond) and intermediate (micro- to millise

291 at the very tip of the loop undergo faster (nano- to picosecond) motions.

292 film, followed by hydrodynamic sputtering of nano- to submicron sized metal droplets.

293 omposition in a three-dimensional space from nano- to submilliscale with high spatial resolution and

294 he formation of shapes and patterns from the nano- to the macroscale.

295 d process covers dimensions ranging from the nano- to the macroscale.

296 hybrid) materials via structuration from the nano- to the mesoscale.

297 that control cellular interactions from the nano- to the microscale, allowing more precise quantitat

298 antages for measuring particle size from the nano- to the microscale.

299 allows a broad separation range from several nano- up to micrometers and enables a superior character

300 Both size (nano- versus micron-sized particles) and anion (nitrate,