ライフサイエンスコーパス: nanosphere

1 ed several binding events of HRP-Ab2 on each nanosphere.

2 of the center-of-mass motion of a levitated nanosphere.

3 e biotin-avidin interaction to a fluorescent nanosphere.

4 ct second harmonic radiation from a metallic nanosphere.

5 e LK peptide produces monodisperse biosilica nanospheres.

6 59 cells compared to free PTX and untargeted nanospheres.

7 continual self-assembly of three-dimensional nanospheres.

8 l (PTX) to the same extent as unbiotinylated nanospheres.

9 in shell of gold over close-packed arrays of nanospheres.

10 lation compared to amine-modified mesoporous nanospheres.

11 l synthesis was developed to prepare uniform nanospheres.

12 s coordination polymer frameworks instead of nanospheres.

13 tion/power of the RIE and the size of the PS nanospheres.

14 s to follow the contour and adhere to the PS nanospheres.

15 gold nanorods from a mixture of nanorods and nanospheres.

16 yielded higher sensitivity than nanorods and nanospheres.

17 erial forms highly crystalline K(4)P(8)Te(4) nanospheres.

18 dly less than homogeneous linewidths of gold nanospheres.

19 culturing cells with GM2/GM3 dimer coated on nanospheres.

20 sual detection using DNA-functionalized gold nanospheres.

21 bridging two sets of DNA-functionalized gold nanospheres.

22 ed on aggregation of DNA-functionalized gold nanospheres.

23 r oligonucleotides using the same set of DNA nanospheres.

24 DOX (e.g., mitochondria) with no detectable nanospheres.

25 gh the supramolecular assembly of amelogenin nanospheres.

26 their accumulation of fluorescently labeled nanospheres.

27 rgy transport is probed by using fluorescent nanospheres.

28 hydrophobic pH sensitive probes directly in nanospheres.

29 ne beta values directly within ion selective nanospheres.

30 model accounts for the ratio of polystyrene nanospheres (300 nm), water, methanol and surfactant in

31 Targeted nanospheres achieved the half maximal inhibitory concent

32 ree kinds: acidic organelles containing only nanospheres, acidic organelles containing nanospheres an

33 entrapped polymer dots inside hollow silica nanospheres acting first as complexing agent for metal i

34 successful approaches using silver film over nanosphere (AgFON) substrates and silica gel coupled wit

35 a sub-1-nm alumina layer on silver film-over-nanosphere (AgFON) substrates.

36 aman spectroscopy (SERS) on silver film over nanosphere (AgFON) substrates.

37 iol monolayer adsorbed on a silver film over nanosphere (AgFON) surface and thereby, it is preconcent

38 Silver film over nanosphere (AgFON) surfaces were functionalized with a m

39 NA nanospheres, the bridging reporter causes nanosphere aggregation.

40 nous doping and anisotropic dispersion of CN nanospheres along the entire NB head nanotubes lead to c

41 tals have been reported to form within lipid nanospheres; alternatively, it has been found in vitro t

42 on exchange takes place between Cl(-) in the nanospheres and a more lipophilic anion in the sample, s

43 ly nanospheres, acidic organelles containing nanospheres and DOX, and other organelles containing DOX

44 w phase-separated bulk MGs containing glassy nanospheres and exhibiting exceptional plasticity under

45 Furthermore, nanospheres and mineral bound specifically to FAP and al

46 volume nanoparticles of other shapes such as nanospheres and nanopallets and report that nanorods exh

47 de (n-CuO) as a function of shape, including nanospheres and nanosheets.

48 magnitude greater than signals from SERRS on nanospheres and nonresonant SERS on nanostars.

49 e brain tumors, composed of three iron oxide nanospheres and one drug-loaded liposome linked chemical

50 ompared to spherical nanostructures (anatase nanospheres and P25).

51 , the former were preloaded with fluorescent nanospheres and plated together with unlabeled MCF-10A c

52 ective elimination of cancer cells: targeted nanospheres and pretargeted radioimmunotherapy.

53 idual nanoparticles to show that hollow gold nanospheres and solid silver nanoparticle dimers linked

54 ed in the gap between a metallic nanorod, or nanosphere, and a metallic substrate.

55 s in nanosecond pulsed laser-irradiated gold nanospheres, and compared our results with a theoretical

56 The nanospheres are derived from the laser pyrolysis of a ni

57 ated in the porous silica, and the resulting nanospheres are extremely resistant to air oxidation.

58 Citrate stabilized gold nanospheres are functionalized with 11-mercaptoundecanoi

59 The nanospheres are of diameter 50 nm, graphitic wall thickn

60 Silica coated gold nanospheres are purified using traditional centrifugatio

61 The values determined in the nanospheres are smaller compared with those in plasticiz

62 Magnetization measurements indicate that nanospheres are superparamagnetic above the blocking tem

63 that we had previously fabricated from gold nanospheres are the significantly lower detection limit

64 Such high-temperature magnetite nanospheres are ubiquitous and abundant in airborne part

65 CRP assay, neutravidin-coated PQQ-doped PMMA nanospheres are used to bind with a biotinylated reporte

66 (nanoLAMPs), consisting of metal-dielectric nanospheres, are a flexible and highly tunable structure

67 A close-packed SiO2 nanosphere array was first deposited on a low-resistivit

68 l detail by using enzyme/DNA films on silica nanospheres as "nanoreactors" to provide nucleobase addu

69 l junction nanopillars that uses polystyrene nanospheres as a lithographic template.

70 ously reported chromoionophore-based optical nanospheres as indicator.

71 heterogeneous ionophore-based ion-selective nanospheres as indicators and chelators for optical titr

72 Here, we present pH-independent optode nanospheres as indicators for complexometric titrations,

73 We present here anion-exchange nanospheres as novel titration reagents for anions.

74 ystal-conversion protocol using preformed Sn nanospheres as templates.

75 wed by the C-terminus, leading to amelogenin nanosphere assembly.

76 e amelogenin dimerization, the first step in nanosphere assembly.

77 m laterally and 16 nm axially for 40-nm gold nanospheres at an imaging rate of 10 frames per second.

78 Raman spectroscopy (SERS) on gold film-over-nanosphere (AuFON) substrates functionalized with bisbor

79 g-term stability of gold to silver film over nanosphere (AuFON, AgFON) substrates functionalized with

80 Heteroaggregation behavior of gold nanospheres (AuNS) in presence of pluronic acid (PA) mod

81 ticles, either gold nanocages (AuNC) or gold nanospheres (AuNS).

82 This work cannot be achieved using gold nanospheres (AuNSs) because the signal of sample color a

83 re describes the development of biotinylated nanospheres based on an ABA-type copolymer comprised of

84 ith MRSA, MSSA, or VRE demonstrated that the Nanosphere BC-GP assay might have led to more appropriat

85 ia for the formation of bicontinuous polymer nanosphere (BPN), namely for copolymers with MW of up to

86 ch mimics can produce monodisperse biosilica nanospheres, but in vitro production of the variety of i

87 ckminsterfullerene, the smallest hydrophobic nanosphere, by molecular dynamics simulations using a st

88 n be readily released from the surface-bound nanospheres (ca. 20,000 PQQ molecules/PMMA particle).

89 of antibodies, enzymes, DNA, and polystyrene nanospheres can be differentiated from the background by

90 the potentiometric response of ion-selective nanospheres can be observed with voltage-sensitive dyes,

91 Nanospheres can, similar to zeolitic classifications, co

92 through folate receptor-targeted hollow gold nanospheres carrying siRNA recognizing NF-kappaB p65 sub

93 eveloped a novel nitrogen-doped carbonaceous nanosphere catalyst by carbonization of polypyrrole, whi

94 grees C for 3 days affords the metal-organic nanosphere [Cd(66)(mu(3)-OH)(28)(mu(3)-O)(16)(mu(5)-NO(3

95 included thin or thick lenses incorporating nanosphere/cipro and ciprofloxacin-HCl-soaked Acuvue len

96 Less than 2 mug/mL of nanosphere/cipro effectively inhibited the proliferation

97 Nanosphere/cipro was then incorporated into HEMA-based c

98 HEMA-based contact lenses polymerized with nanosphere/cipro were transparent, effectively inhibited

99 f the nanosphere-encapsulated ciprofloxacin (nanosphere/cipro) was tested by using liquid cultures of

100 The TPPL spectra of these single Au nanosphere clusters closely resemble their corresponding

101 et sensor platform and functionalized carbon nanospheres (CNSs) labeled with horseradish peroxidase-s

102 In this work, we designed charged ~5 nm Au nanospheres coated with binary mixed-charge ligand monol

103 The stable nanosphere complexes contain multiple PLGA-polycation na

104 id-metal nanomedicine, based on a core-shell nanosphere composed of a liquid-phase eutectic gallium-i

105 pectively, are successfully characterized in nanospheres composed of triblock copolymer Pluronic F-12

106 eral phase appears as aggregates of 20-30-nm nanospheres, consistent with amorphous calcium carbonate

107 he preparation of multifunctional core-shell nanospheres consisting of a core of metal clusters and a

108 The nanospheres contain a lipophilic cation for which the co

109 Mesoporous carbon nanospheres containing porphyrin-like metal centers (den

110 measuring the pH and Na(+) responses of the nanospheres (containing solvatochromic dyes and ion exch

111 obtained by measuring the pH response of the nanospheres (containing the probes and ion exchanger) fo

112 Mediated by hollow gold nanospheres, controllable cytoplasmic delivery of siRNA

113 solvatochromic dyes were encapsulated in the nanosphere core, ion sensing nanospheres were explored f

114 poration of a lipophilic pH indicator in the nanosphere core.

115 it enhanced photocatalytic activity over the nanosphere counterparts with an identical crystal phase

116 ich, when conjugated to glucose-based carbon nanosphere (CSP), passed the blood-brain barrier, induce

117 Internally structured self-assembled nanospheres, cubosomes, are formed from a semicrystallin

118 hich self-assembles to fibrils, platelets or nanospheres depending on the solvent composition.

119 loped as the resonant wavelength dictated by nanosphere diameter.

120 n their preparation allowed for control over nanosphere diameters from 70 to 460 nm.

121 The averaged intensity of the Au nanosphere dimers and linear trimers is ~7.8 x 10(3) and

122 cultured with GM2 and GM3 cocoated on silica nanospheres, displayed stronger and more consistent moti

123 inopyridine-functionalized mesoporous silica nanosphere (DMAP-MSN) has been synthesized and character

124 er electron-hole recombination rate than the nanospheres due to the following three reasons: (i) grea

125 lization method was applied to tracking gold nanospheres during live endocytosis events.

126 Very recently, ion-selective nanosphere emulsions were introduced that exhibit ion-ex

127 The biotinylated nanospheres encapsulate paclitaxel (PTX) to the same ext

128 Bactericidal activity of the nanosphere-encapsulated ciprofloxacin (nanosphere/cipro)

129 anti-CD44 antibody, StA and the biotinylated nanospheres encapsulating PTX.

130 Second, platinum nanosphere ensembles were mapped using platinum-modified

131 The ion-selective nanospheres exhibit excellent selectivity and respond to

132 This new type of core-shell nanospheres exhibits excellent photoluminescence propert

133 Here we demonstrate a silicon nanosphere fabrication process based on an optical fibre

134 able method for the assembly of bicontinuous nanospheres, filomicelles and vesicular, multilamellar a

135 ic mobility, DOX fluorescence intensity, and nanosphere fluorescence intensity distributions of indiv

136 e formation of a monolayer of self-assembled nanospheres, followed by custom-etching to produce nanom

137 Highly uniform Au "film over nanospheres" (FON) substrates together with use of Raman

138 solvents and incorporated into ion selective nanospheres for K(+), Na(+), and H(+).

139 vinylpyrrolidone)-encapsulated hollow sulfur nanospheres for sulfur cathode, allowing unprecedented c

140 s of novel prosthetic group loaded polymeric nanospheres for use in high-sensitivity bioaffinity assa

141 We propose a model for nanosphere formation via oligomers, and we predict that

142 t into the molecular mechanism of amelogenin nanosphere formation, we manipulated the interactions be

143 s containing high concentrations of magnetic nanospheres formed by direct precipitation within the ho

144 uced by catechin to form graphene-zinc oxide nanospheres (G-ZnO NSs; average diameter of (45.3 +/- 3.

145 at appear to be primarily random coil in the nanosphere-gel adopt a beta-strand structure and are les

146 dynamics of full-length amelogenin within a nanosphere-gel and on the surface of HAP.

147 rements and theoretical predictions for gold nanospheres (GNS) and nanorods (GNR).

148 12, 7, and 3 times higher than those of gold nanospheres, gold nanocubes, and gold nanorods, respecti

149 side the curvature of highly packed metallic nanosphere gratings.

150 The CMP slurry consists of mainly SiO2 nanospheres, H2O2, and malic and citric acids, which are

151 f beta-sheets by up to 75%, while amelogenin nanospheres had predominantly random-coil structure.

152 Self-assembly of amelogenin protein into nanospheres has been recognized as a key factor in contr

153 th the defect structure Fe(0.74)Sn(5) of our nanospheres, has been resolved by synchrotron X-ray diff

154 For example, hollow gold nanospheres (HAuNS) have been shown to generate intense

155 polyethylene glycol (PEG)-coated hollow gold nanospheres (HAuNS) mixed with ethiodized oil for improv

156 Pegylated hollow gold nanospheres (HAuNS, diameter=40 nm) coated with MC1R ago

157 er of interconnected amorphous hollow carbon nanospheres helps isolate the lithium metal depositions

158 s was studied for both hollow and solid gold nanospheres (HGNs and SGNs, respectively) using femtosec

159 romagnetic coupling processes in hollow gold nanospheres (HGNs) and HGN aggregates are described.

160 ring (SERS) from nonaggregated, hollow, gold nanospheres (HGNSs).

161 rication method for hierarchically porous Si nanospheres (hp-SiNSs), which consist of a porous shell

162 e highly negatively charged MS2, fr, and the nanospheres impaired their adsorption onto DOM adlayers

163 y curves of randomly distributed fluorescent nanospheres in agarose gel were obtained and fitted with

164 genin exists primarily as ~26 nm in diameter nanospheres in bulk solution at a pH of 8.0 studied by d

165 teractions by simple mixing, thereby forming nanospheres in seconds with diameters <200 nm.

166 Amelogenin forms into nanospheres in solution, while its association with hydr

167 PQQ released from the nanospheres in the presence of 40% acetonitrile is capab

168 loaded into poly(methyl methacrylate) (PMMA) nanospheres in the presence of methanol.

169 e Gram-Positive Blood Culture (BC-GP) assay (Nanosphere Inc., Northbrook, IL) for detection of common

170 tory virus nucleic acid test SP (RVNAT(SP)) (Nanosphere Inc., Northbrook, IL) to detect influenza A v

171 leic acid test for investigational use only (Nanosphere, Inc., Northbrook, IL) for the identification

172 , MA) and the Verigene BC-GN (BC-GN) assays (Nanosphere, Inc., Northfield, IL) for the identification

173 tra may be obtained using a single composite nanosphere, including dipole-dipole Fano resonances and

174 The nanospheres incorporate an ionic solvatochromic dye (SD)

175 e will be only expelled from the core of the nanosphere into the aqueous solution at the end point at

176 ed photoinduced method for converting silver nanospheres into triangular silver nanocrystals--so-call

177 A new family of nanospheres is made by complexation of divalent metals (

178 that is tethered to the pore openings on the nanosphere, is synthesized and tested.

179 ork, interconnected mesoporous hollow carbon nanospheres, is reported as an effective sulfur host to

180 Interestingly, unlike nanospheres, larger-sized hydrogel nanodiscs and nanorod

181 e molecules on a 330-nanometer silver-coated nanosphere lattice using incident light of wavelength 53

182 t occurs, positive charges are formed in the nanosphere, leading to a decrease in the oxidation state

183 face confined Ag nanoparticles fabricated by nanosphere lithography (NSL) are presented.

184 This process used nanosphere lithography (NSL) encompassing the deposition

185 The SiO2 NPA was fabricated by the nanosphere lithography (NSL) techniques.

186 Herein, nanosphere lithography (NSL) was used to fabricate unifo

187 y, arrays of immobilized AgNPs fabricated by nanosphere lithography (NSL) were used to study AgNP sul

188 terned into a nanomesh by the combination of nanosphere lithography and reactive ion etching and eval

189 anostructured catalysts were created using a nanosphere lithography lift-off process and an applied-b

190 Nanosphere lithography, an inexpensive and high throughp

191 spacing fabricated by multilayer deposition, nanosphere lithography, and multistep reactive ion etchi

192 based on combination of soft lithography and nanosphere lithography, and perform a comprehensive stru

193 findings indicate that the combination of PS nanosphere lithography, followed by the spin-coating of

194 in unique MnxGe1-x nanomeshes fabricated by nanosphere lithography, in which a Tc above 400 K is dem

195 By means of nanosphere lithography, the SERS substrate was prepared

196 A4 on Ag nanoparticle surfaces fabricated by nanosphere lithography.

197 Core-shell nanospheres loaded with an antibiotic can be incorporate

198 The nanosphere matrix is composed of bis(2-ethylhexyl) sebac

199 , magnetic-fluorescent semiconductor polymer nanospheres (MF-SPNs) have been synthesized by encapsula

200 ich is also referred to as a metal film over nanosphere (MFON), is presented.

201 cized PVC membranes, indicating a more polar nanosphere microenvironment and possible uneven distribu

202 rker supported on Au deposited monodispersed nanospheres monolayers (Au-MNM) of polystyrene offers an

203 .8 x 10(3) and ~7.0 x 10(4) times that of Au nanosphere monomers, respectively.

204 Highly monodisperse porous silicon nanospheres (MPSSs) are synthesized via a simple and sca

205 nanoparticle (AuNP)-capped mesoporous silica nanosphere (MSN)-based intracellular drug delivery syste

206 most commonly used morphologies: nanostars, nanospheres, nanorods, and nanoplates is designed.

207 phasic (Al/Al(2)O(3)) nanostructures such as nanospheres, nanowires and nanoloops using a single sour

208 ed reactions and produces hollow metal-oxide nanospheres (Ni0.18 Mn0.45 Co0.37 Ox ) or core-shell met

209 e Gram-positive blood culture (BC-GP) assay (Nanosphere, Northbrook, IL) is a molecular method for th

210 Verigene Gram-Positive Blood Culture (BC-GP; Nanosphere, Northbrook, IL), and matrix-assisted laser d

211 The linear arrays (chains) of nanospheres observed as intermediate states before the m

212 We synthesized monodisperse nanospheres of an intermetallic FeSn(5) phase via a nano

213 s from East Antarctic granulites are 5-30 nm nanospheres of metallic Pb.

214 driven electron transfer occurring in single nanosphere oligomer systems with a 3% yield, a phenomeno

215 n the plasmonic hot spots of individual gold nanosphere oligomers, corroborated by open-shell density

216 n plasmonic hot spots within individual gold nanosphere oligomers.

217 ages MS2, fr, GA, and Qbeta) and polystyrene nanospheres onto a positively charged model sorbent surf

218 suppressed the adsorption of the viruses and nanospheres onto the model surface.

219 The reported methods of micro- and nanosphere optode fabrication, however, suffer from vari

220 expansion followed by contraction along the nanosphere or nanorod radial direction driven by a trans

221 phnia dubia relative to parent CuO material (nanosphere or rod).

222 n that of PTX applied in either non-targeted nanospheres or free drug approaches.

223 ed in the digestion of Abeta microfibrils to nanospheres or nanofilaments by protease XIV or alpha-ch

224 rarchies such as superlattices and composite nanospheres or nanowires.

225 Both random and ordered nanosphere patterns have been explored for fabricating h

226 intained and that using these HRP-containing nanospheres, peroxide production could be sensed locally

227 cence phenomenon due to the silver film over nanosphere plasmonic substrate.

228 sulting helical polymer-metal complex (HPMC) nanospheres present two interesting properties: (a) thei

229 cological implications of copper oxide (CuO) nanospheres relative to CuO nanorods used in nanoenerget

230 The indicating nanospheres rely on a weaker extraction of the analyte o

231 onditions while approximately 40 nm diameter nanospheres remained intact even under aggressive condit

232 dride-co-L-DOPA) (PBMAD), to non-bioadhesive nanospheres resulted in an enhancement of particle uptak

233 ces using single molecule assays that employ nanosphere rotational probes to achieve high torque reso

234 anti-FBP antibody and protein-A-coated gold nanosphere sandwich assay extended the detection limit t

235 Moreover, targeted nanospheres selectively eliminated CD44 positive SUM159

236 c aluminum oxide (AAO) membranes with silica nanospheres self-assembled in the channels.

237 responses from several individual solid gold nanosphere (SGN) dimers, which we prepared by a bottom-u

238 er times were also determined for solid gold nanospheres (SGNs) having radii spanning 9-30 nm, with a

239 n situ compression experiments on individual nanospheres show that the amorphous carbon nanospheres w

240 Both the chelating and the indicating nanospheres showed good selectivity and a wide working p

241 RAIL onto liposomes--synthetic lipid-bilayer nanospheres--similarly augmented activity.

242 ticles of various size and type: polystyrene nanosphere size standards, lipid droplets (LDs), and lar

243 The relationship between nanosphere size, surface charge, PLGA-polycation composi

244 Fresh kerosene nanosphere soot (ns-soot) exhibited a mean M.A.C and sta

245 Semiconducting polymer nanospheres (SPNs) have been synthesized and encapsulate

246 y hydrophobic protein self-assembles to form nanosphere structures under certain solution conditions.

247 strategies now also yield shapes other than nanospheres, such as anisotropic metal nanostructures wi

248 Consistent findings for viruses and nanospheres suggest that the coadsorbate effects describ

249 ddition, a simple modification on the sulfur nanosphere surface with a layer of conducting polymer, p

250 Silver film over nanosphere surfaces were functionalized with a two-compo

251 Selective removal of polystyrene nanosphere templates from a lyotropic liquid crystal-tem

252 f the amelogenin protein self-assembled into nanospheres that are necessary to guide the formation of

253 arge-scale synthesis of single-crystal ceria nanospheres that can reduce the polishing defects by 80%

254 tone (PCL) was used to synthesize core-shell nanospheres that encapsulated ciprofloxacin.

255 When combined with a solution containing DNA nanospheres, the bridging reporter causes nanosphere agg

256 Owing to the very small size of the nanospheres, the suspension containing the particles is

257 uences starting from 10 mJ cm(-2) for single nanospheres, their ensembles and aggregated clusters in

258 w that long-circulating vehicles need not be nanospheres, they also lend insight into possible shape

259 In nanospheres, this pH-sensitive (pKa = 7.3), photochemica

260 tic times for Brownian motion of fluorescent nanospheres through the volume elements.

261 hway for the conversion of citrate-capped Ag nanospheres to AgAu nanocages; importantly, the hollowin

262 The ability of these nanospheres to encapsulate is demonstrated with examples

263 tilize unsupported sub-wavelength dielectric nanospheres to generate near-fields with adjustable stru

264 Here, we use heated optically levitated nanospheres to investigate the non-equilibrium propertie

265 The differential distribution of the nanospheres to various tissues following uptake suggests

266 properties of gold nanoparticles, e.g. gold nanospheres, to simultaneously obtain enhanced intracell

267 een developed consisting of tyrosine-derived nanospheres (TyroSpheres) with encapsulated anti-prolife

268 th dsDNA and NeutrAvidin-coated, fluorescent nanospheres under conditions that allow enzyme binding b

269 of the photothermal conversion by solid gold nanospheres under near-infrared excitation with a short

270 en a single serum protein molecule on a gold nanosphere used in biomedical imaging may increase the s

271 pairs and/or chains were evaluated with the Nanosphere Verigene Gram-positive blood culture (BC-GP)

272 ) nasopharyngeal specimens, we evaluated the Nanosphere Verigene RV+ and the Focus Diagnostics Simple

273 In this study, a gold nanosphere was used as the plasmonic donor, while the me

274 aking as an example the case of two touching nanospheres, we show for the first time, to our knowledg

275 The ~5 nm nanospheres were assembled into ~20 nm diameter nanoclus

276 Na(+)- and H(+)-selective nanospheres were characterized by absorbance and fluores

277 psulated in the nanosphere core, ion sensing nanospheres were explored for cellular ion imaging in Di

278 Complex polymeric nanospheres were formed in water from comb-like amphiphi

279 Here, 200nm PLGA/PVA nanospheres were formulated for the systemic delivery of

280 Results indicated nanospheres were more stable in water and slowly release

281 The amorphous carbon nanospheres were synthesized via a low-cost, scalable an

282 Nb(2)O(5) nanorods and nanospheres were synthesized, and their photocatalytic a

283 As an example, the nanospheres were used to measure the Na(+) level in comm

284 trol of light waves and currents in metallic nanospheres which applies independently of the nonlinear

285 al-boron (M-B, M=Fe, Co, Ni, NiCo) composite nanospheres which facilitates the formation of ultrathin

286 noclusters dissociated into primary ~5 nm Au nanospheres, which also did not adsorb any detectable se

287 f soluble monomers leads to the formation of nanospheres, which then undergo ripening and structural

288 nce marker detection system (Verigene BC-GN; Nanosphere) while antimicrobial stewardship practices re

289 formation via oligomers, and we predict that nanospheres will break up to form oligomers in mildly ac

290 and demonstrate that amorphous porous carbon nanospheres with a thin outer shell can simultaneously a

291 strategy to obtain reproducible probes using nanospheres with alternating metal and reporter-filled d

292 l nanospheres show that the amorphous carbon nanospheres with an optimized structure can sustain beyo

293 ricate silica nanopollens (mesoporous silica nanospheres with rough surfaces), which show enhanced ad

294 ized polymer dots in hollow silica or carbon nanospheres with size-selective micropores is presented.

295 The coupling of hollow carbon nanospheres with triblock copolymers is a promising stra

296 initial deposition of a monolayer of silica nanospheres (with diameter of approximately 330 nm) on a

297 antum plasmonic properties of small metallic nanospheres, with direct application to understanding an

298 Formation of these metallic nanospheres within annealed zircon effectively halts the

299 It is found that the glassy nanospheres within the shear band dissolve through mecha

300 The resulting nanospheres, worm-like micelles, or vesicles interact in