ライフサイエンスコーパス: surface chemistry

1 it is principally governed by the implant's surface chemistry.

2 ryogels causes no significant changes in the surface chemistry.

3 ts role over time through alterations in its surface chemistry.

4 synthetic routes, low-toxicity and tuneable surface chemistry.

5 ely 90% loading efficiency using phosphonate surface chemistry.

6 nted attachment directed by quantum dot (QD) surface chemistry.

7 primary concern is the effect of salinity on surface chemistry.

8 tion of anticoagulants and/or improvement of surface chemistry.

9 eir properties are highly dependent on their surface chemistry.

10 pation into electronic degrees of freedom in surface chemistry.

11 tte is strongly affected by its geometry and surface chemistry.

12 the type of anion or by solution versus the surface chemistry.

13 ped CdTe NC ink by taking advantage of novel surface chemistry.

14 cies requires a fundamental understanding of surface chemistry.

15 cience for the applications in catalysis and surface chemistry.

16 and dispersal can be inhibited by modifying surface chemistry.

17 the detailed physical environment, flow, and surface chemistry.

18 e substrate adhesion combined with desirable surface chemistry.

19 aluate protein binding to NPs with different surface chemistry.

20 s depends on factors such as SWNT length and surface chemistry.

21 st to initiate from the peaks, regardless of surface chemistry.

22 gh resonant vibrational excitations to steer surface chemistry.

23 rks using a combination of anion effects and surface chemistry.

24 anding of boundary conditions independent of surface chemistry.

25 , ambient processing conditions, and diverse surface chemistry.

26 r the validation and characterization of the surface chemistry.

27 allic surfaces is a fundamental challenge of surface chemistry.

28 (GO) is an antimicrobial agent with tunable surface chemistry.

29 ses, stability, biocompatibility, and a rich surface chemistry.

30 ctrally broad emission and less well-defined surface chemistry.

31 ed with the different assay requirements and surface chemistry.

32 directly synthesized and undergo interfacial surface chemistry.

33 P patterns was relatively independent of the surface chemistry.

34 B5075) exhibits a distinctly electronegative surface chemistry.

35 hes to elucidate its molecular structure and surface chemistry.

36 ng-opening reaction while stabilizing the Si surface chemistry.

37 per immobilized SAv by choosing appropriate surface chemistry.

38 action science and nanoscale regio-selective surface chemistry.

39 regnant women to probes of varying sizes and surface chemistries.

40 ction of anti-PEG abs and compared three PEG surface chemistries.

41 other nanomaterial types and five different surface chemistries.

42 nitude by engineering specific interface and surface chemistries.

43 rticle binding, without the need for complex surface chemistries acting as blocking agents.

44 Herein we investigate how surface chemistry affects the PK profile and organ distr

45 tic acid) nanoparticles presenting different surface chemistries, after administration by convection-

46 temperature pre-treatments influenced their surface chemistry, aggregation and ability to align at t

47 ties such as size, shape, deformability, and surface chemistry all play a role in nanomedicine drug d

48 se control of a nanomaterial's structure and surface chemistry allow for a high degree of tunability

49 ch a protecting group strategy applied to on-surface chemistry allows self-assembly structures to be

50 nO are described in detail, particularly its surface chemistry, along with the role of defects in gov

51 ilities offered by leveraging nontraditional surface chemistries and assembly environments to control

52 lymeric nanoparticles of different sizes and surface chemistries and of a much smaller fluorescently

53 oidosomes with a range of membrane textures, surface chemistries and optical properties.

54 ve been realized by precisely tailoring pore surface chemistries and pore geometries, a single system

55 d Qbeta) to five model surfaces with varying surface chemistries and to three dissolved organic matte

56 ion measurements, critical for understanding surface chemistry and accelerating catalyst selection.

57 y the bead surface chemistry and the BD-UNCD surface chemistry and apply dielectrophoresis to improve

58 major roles in the science and technology of surface chemistry and biochemical sensing.

59 A fundamental challenge in surface chemistry and catalysis relates to the determina

60 Surface chemistry and catalysis studies could significan

61 uilding upon the d-band reactivity theory in surface chemistry and catalysis, we develop a Bayesian l

62 les (NPs) is a standard method to control NP surface chemistry and charge.

63 k for understanding the interplay between NC surface chemistry and colloidal stability.

64 ects that irreversible oxidation have on the surface chemistry and electrochemical properties of MXen

65 that by controlling the liquid cell membrane surface chemistry and electron beam conditions, the dyna

66 ces understanding of the correlation between surface chemistry and electronic/transport properties of

67 cal disinfection can produce CNTs exhibiting surface chemistry and environmental behavior distinct fr

68 The large specific surface area, versatile surface chemistry and exceptional mechanical properties

69 here both the physicochemical properties (Ag surface chemistry and fluorescence) of the NC core and t

70 This intimate connection between LAO surface chemistry and LAO/STO interface physics bears fa

71 ed parameters in the natural system, such as surface chemistry and material changes, may not be as in

72 egative carbon emission." Recent advances in surface chemistry and material synthesis have resulted i

73 Surface chemistry and mechanical stability determine the

74 l method, and characterized the evolution of surface chemistry and morphology using a suite of spectr

75 To reflect the importance of surface chemistry and nanoparticle core composition in t

76 Surface chemistry and nanoscopic method are applicable t

77 advance our fundamental understanding of the surface chemistry and nucleation behavior of iron(III) (

78 directly observe a close correlation between surface chemistry and phase distribution from homogeneit

79 as allowed for fundamental insights into the surface chemistry and photochemistry of numerous probe m

80 loped technique offers detailed insight into surface chemistry and physics of diamond with other mate

81 interplay between diffusion, advection, and surface chemistry and present the design of a noncontact

82 ial physical and chemical properties-such as surface chemistry and properties like cell attachment or

83 ies for achieving exquisite control over the surface chemistry and properties of nanocomposites with

84 Weathering processes that changed the surface chemistry and roughness of MPs impacted MP affin

85 mbled by tedious methodologies, with complex surface chemistry and small sizes.

86 ilizes the photoactive layer by changing the surface chemistry and suppressing methylammonium loss.

87 h 5-15% H2O2 and investigated the changes in surface chemistry and the adsorption behavior of ammoniu

88 we establish clear relationships between QD surface chemistry and the band edge positions of ligand/

89 We systematically vary the bead surface chemistry and the BD-UNCD surface chemistry and

90 ese important parameters are affected by the surface chemistry and the blocking steps conducted durin

91 A mechanism of mutual modulation between the surface chemistry and the bulk microstructure is formula

92 However, the interplay of the surface chemistry and the bulk microstructure remains la

93 Such efforts require knowledge of matrix surface chemistry and the cell responses they elicit.

94 t, recording information on Earth's earliest surface chemistry and the low oxygen primordial biospher

95 ntitative relationships between the material surface chemistry and the protein adsorption characteris

96 to modifying the pore geometry and internal surface chemistry and thus the function of open-framewor

97 e atoms, is an important approach to tune NP surface chemistry and to optimize NP catalysis for chemi

98 h a strategy could be of great importance in surface chemistry and widely applied to control on-surfa

99 We show here yet unveiled details of surface chemistry and, based on these new data, formulat

100 take advantage of the diverse morphologies, surface chemistries, and functionalities of proteins for

101 were tailorable by the dendrimer generation, surface chemistry, and acidity.

102 emical parameters, namely, size, elasticity, surface chemistry, and biopersistence.

103 tate of the art in nanoparticle development, surface chemistry, and biosensing mechanisms, discussing

104 operties such as high aspect ratio, flexible surface chemistry, and control over structure and morpho

105 ted the effects of nanomaterial size, shape, surface chemistry, and exposure conditions on toxicity.

106 ity to control the composition, size, shape, surface chemistry, and functionality of materials.

107 ocks, giving control over their size, shape, surface chemistry, and membrane permeability.

108 , we combine principles of microengineering, surface chemistry, and molecular biology to address the

109 de (PbS and PbTe) HNPs with tailorable size, surface chemistry, and near-IR absorption.

110 control over the size, shape, architecture, surface chemistry, and properties of 1D nanocrystals.

111 sitive to the probe's sharpness, but not its surface chemistry, and the force did not depend on cell

112 s method allows for precise control over the surface chemistry, and therefore the transport propertie

113 tion, excellent biocompatibility, tailorable surface chemistry, and tunable sizes and shapes.

114 electrohydrodynamic cojetting followed by a surface chemistry approach to maximize cell-adhesive cha

115 can overcome these limitations, but improved surface chemistries are still needed to guarantee detect

116 rticular, the influence of particle size and surface chemistry are discussed, in order to understand

117 ed surfaces showed a tailored topography and surface chemistry as determined by SEM microscopy and RA

118 (iii) polyethylene glycol is not as benign a surface chemistry as is generally supposed.

119 monolithic ceramic devices with homogeneous surface chemistry as well as homogeneous physical proper

120 from organic, inorganic, organometallic and surface chemistry as well as molecular magnetism illustr

121 The concept that surface chemistry at the (sub)nanometer scale dictates w

122 Further, it provides a rich surface chemistry available for nano-interfacing and a s

123 f probe proteins on a sensor surface involve surface chemistry-based techniques.

124 ultrasmall metal NPs with the same size and surface chemistry but different densities, we found that

125 e properties are heavily influenced by their surface chemistry, but a detailed understanding of the s

126 ects on the cell membrane depending on their surface chemistry by molecular dynamics simulations.

127 How nanoparticle size, shape, and surface chemistry can affect their accumulation, retenti

128 oparticle properties such as size, shape and surface chemistry can be controlled to improve their per

129 er-soluble, photostable, nontoxic, and their surface chemistry can be easily modified.

130 t provides a framework for understanding how surface chemistry can be used to modulate the electronic

131 We also discover that surface chemistry can significantly enhance the cyclic p

132 of NPSi prober was proposed by studying the surface chemistry change of NPSi and metal ions immersed

133 d rate of dissolution, particle destruction, surface chemistry change(s), and new particle formation.

134 We also studied surface chemistry changes during the treatment period us

135 their carbon based source results in tunable surface chemistry, chemical versatility, low cost, and b

136 ity is an effect where surface roughness and surface chemistry combine to generate surfaces which are

137 nd resemble human HDLs in their size, shape, surface chemistry, composition, and protein secondary st

138 Our work shows the limitations of applying surface chemistry concepts derived for binary rocksalt o

139 yses of adsorbent pore size distribution and surface chemistry confirmed that neither heating method

140 , which are additive in nature and driven by surface chemistry considerations and material-specific p

141 Tailoring the MXene surface chemistry could achieve this goal, as density fu

142 is review surveys the size, composition, and surface chemistry-dependent properties of semiconductor

143 ge of accessible inorganic cores and tunable surface chemistries dramatically increased, expanding th

144 n on <100>, a finding that adds control over surface chemistry during the device fabrication.

145 Pd/C samples to decouple the electronic and surface chemistry effects on catalytic performance.

146 ch allows to separate pore size effects from surface chemistry effects.

147 Overshadowed by size-, shape-, and surface-chemistry effects, the impact of the particle co

148 bine semiconducting properties with tailored surface chemistry, elastic mechanical properties and che

149 g, which is of interest in material science, surface chemistry, electrochemistry, and other fields.

150 rticles with nonspherical shapes and complex surface chemistries enabling the formation of sophistica

151 chiral stationary phases with very different surface chemistries, encompassing derivatized polysaccha

152 raphite interface and correlated back to the surface chemistry evolution.

153 ign parameters (CNDPs), namely, size, shape, surface chemistry, flexibility/rigidity, architecture, a

154 On-surface chemistry for atomically precise sp(2) macromole

155 ranslate into broad interest in this type of surface chemistry for biosensor development.

156 This study reveals a richer surface chemistry for transition metals than previously

157 atility to implement nanoparticles and other surface chemistry for various applications.

158 MPs) paired with the wide range of available surface chemistries has strongly positioned PMPs in the

159 lloids in optics, biology, and energy, their surface chemistry has become a topic of intensive resear

160 e interplay between particle size, shape and surface chemistry has not been well investigated especia

161 the interface it provides suggest that this surface chemistry has the potential to enable fundamenta

162 Fine carbon particles with engineered surface chemistry have been shown to stabilize oil-in-wa

163 ost two centuries, many aspects of 2D chiral surface chemistry have yet to be addressed.

164 coatings and the modification of the copper surface chemistry help to stabilize the lithium metal su

165 The innovative surface chemistry helps to reduce the contact angle of t

166 Due to their low production costs, unique surface chemistry, high chemical and thermal stability,

167 lobular counterparts of identical volume and surface chemistry, highlighting the importance of the sh

168 of 600 microscopy images of three different surface chemistries (hydrophilic and hydrophobic) and is

169 ultrathin, oligoethylene glycol-based mixed surface chemistry imposed on piezoelectric quartz discs.

170 d films of conducting polymers with multiple surface chemistries in a one-step process and to incorpo

171 tion is strongly dictated by carbon nanotube surface chemistry in accordance with the enzyme dipole m

172 The surface chemistry in colloidal nanocrystals on the final

173 , focusing on the fundamental role played by surface chemistry in controlling the interaction of NPs

174 to interfacial conductivity and the role of surface chemistry in dictating these properties.

175 lecular simulation results indicate that the surface chemistry in micropores is tunable thereby influ

176 the complexity of the pore architecture and surface chemistry in MOFs present new challenges.

177 nd for identifying the role of heterogeneous surface chemistry in molecular dynamics.

178 These results isolate the critical role of surface chemistry in the photoluminescence of small meta

179 trate the pivotal role of metal nanoparticle surface chemistry in tuning and optimizing emergent opto

180 of colloidal QDs and the influence of their surface chemistry, in particular, dipolar ligands and ex

181 anganite surfaces, and trace their origin to surface-chemistry-induced stabilization of ordered Jahn-

182 Specific size, shape and surface chemistry influence the biological activity of n

183 c-acid-functionalized proteins with distinct surface chemistries into six unique lattices composed of

184 erging top-down lithography and bottom-up on-surface chemistry into technology.

185 Optimum surface chemistry is a key consideration to modulate the

186 carrier, suggesting that tuning of the oxide surface chemistry is as relevant as the selection of the

187 m solid oxide fuel cells to catalysts, their surface chemistry is poorly understood at the molecular

188 This hierarchical surface chemistry is widely applicable to many analytes

189 l cathode host for unveiling the challenging surface chemistry issue in Li-S batteries.

190 iciency on nanotopological surface identical surface chemistry (<2% cell-capture efficiency).

191 ibrils combined with their highly functional surface chemistry make them an attractive new food ingre

192 trating that pores of varying geometries and surface chemistries may be reliably accessed through com

193 nduce a controlled transition from redox- to surface chemistry-mediated growth pathways, resulting in

194 sult of electrostatic assumptions within the surface chemistry model and provide a strong constraint

195 dots (QDs), can be tuned over 2.0 eV through surface chemistry modification.

196 porous particles (SPP, 2.7 mum) of different surface chemistries, namely, teicoplanin, cyclofructan,

197 tes is a first step toward understanding the surface chemistry necessary for efficient CO electroredu

198 uctural features, electronic properties, and surface chemistry of 2D nanostructures that dictate thei

199 The surface chemistry of a prepared carbon cryogels pyrolyze

200 within this paper by examining the peculiar surface chemistry of a relatively new bioceramic, silico

201 ked aromatic oligoamide film that mimics the surface chemistry of an RO polyamide membrane was synthe

202 As predicted by the surface chemistry of anatase TiO(2) nanoparticles, querc

203 s reactions at nanoscale by manipulating the surface chemistry of both sol-gel nanoparticles (NPs) an

204 The modular surface chemistry of CDs together with their photostabil

205 raphic and etching techniques may affect the surface chemistry of colloidal nanomaterials.

206 s progress toward controlling the shapes and surface chemistry of colloidal nanoparticles, spatial co

207 work proposes new insights into manipulating surface chemistry of electrode materials to control oxyg

208 Precisely tailoring surface chemistry of layered materials is a growing need

209 odel could be a more general picture for the surface chemistry of metal oxide nanocrystals with impor

210 ich presents a longstanding challenge in the surface chemistry of metal oxides.

211 by the iridescent nanostructure and gradient surface chemistry of Morpho butterflies and involves phy

212 sis but also for the characterization of the surface chemistry of nanomaterials stabilized with thiol

213 Here, we will review the surface chemistry of nanoparticles and catalytic reactio

214 The size, shape and surface chemistry of nanoparticles can greatly impact ce

215 l properties, including size, clustering and surface chemistry of nanoparticles regulate their cellul

216 The characterization of the surface chemistry of nanoparticles using infrared spectr

217 deep insight into the role of defects in the surface chemistry of oxides can be gained, as will be de

218 This work investigates the effect of surface chemistry of polymeric nanoparticulate drug deli

219 ot enough often taken into consideration the surface chemistry of ruthenium nanoparticles starts to b

220 Recent advancements indicate the surface chemistry of Si-NCs plays a key role in determin

221 In this work, we investigate the radical surface chemistry of silicon with a range of organochalc

222 for controlling the plasmonic properties and surface chemistry of small metal nanoparticles.

223 The new crosslinking strategy preserves the surface chemistry of the active layer beneath, and at th

224 It is shown that the surface chemistry of the active material in a flow elect

225 uNPs) can be controlled by the nature of the surface chemistry of the AuNPs.

226 The tunable surface chemistry of the CDs was exploited to synthesize

227 ional Synchrotron Light Source can probe the surface chemistry of the curved and inhomogeneous cuticl

228 as a function of the applied voltage and the surface chemistry of the dielectric layer.

229 Herein, we show that the surface chemistry of the guest nanoparticles and the [Ca

230 To this end, controlling the size and surface chemistry of the materials is crucial for such a

231 ra reveals characteristic differences in the surface chemistry of the nanoparticles.

232 ner, where the interplay of the quantity and surface chemistry of the NPs regulates the translocation

233 By controlling the surface chemistry of the paper, it is possible to print

234 the details of the transfer reaction and the surface chemistry of the resulting sterically stabilized

235 By controlling the surface chemistry of the substrate, we produce large are

236 whose magnitude and direction depends on the surface chemistry of the suspended particles, and whose

237 re attractive or repulsive, depending on the surface chemistry of the suspended particles.

238 properties (e.g., size, surface charge, and surface chemistry) of these nanomaterials influence thei

239 their well-ordered pore networks and tunable surface chemistries, offer a versatile platform for prep

240 that the transversal concept of integrative surface chemistry offered by polydopamine in combination

241 periments, this work explores the effects of surface chemistry on AMD-generated INP behavior before a

242 ctrochemical DNA sensors prepared using this surface chemistry on carbon with electrochemical chlorin

243 de important new insights into the impact of surface chemistry on microscopic spatial variations in h

244 r unanticipated effects of varying dendrimer surface chemistry on their encapsulation or hosting effi

245 ds to study the influence of size, shape and surface chemistry on their uptake and transport across i

246 nctionalized single-walled CNTs (SWNTs) with surface chemistries optimized for delivery of plasmid DN

247 Al," without any modification of the support surface chemistry or electrolyte additives.

248 may serve as a platform for studying silica surface chemistry or hydroxyl-mediated reactions.

249 /ion transport have been studied before, the surface chemistry or the spatially heterogeneous diffusi

250 of this emerging platform in the context of surface chemistry patterning, redox imaging, chemical an

251 NP surface chemistry played an important role in the altera

252 to various tissues following uptake suggests surface chemistry plays a significant role in their loca

253 stics of carbon-based nucleants: appropriate surface chemistry, porosity and/or roughness are require

254 ze are designed by tweaking size (2-250 nm), surface chemistries (positive, or negatively charged), m

255 les within biological media, and discuss how surface chemistry presentation may affect this process a

256 ctivation of oral pathogens, modification of surface chemistry/properties, resin polymerization, impr

257 Regardless of surface chemistry, PSL-infused textured surfaces exhibit

258 k differentiation based on the nanomaterials surface chemistry, purity and agglomeration state.

259 (kaolinite vs glass beads) and nanoparticle surface chemistry (PVP, citrate, or humic acid) on alpha

260 sinusoids, which transforms the nanoparticle surface chemistry, reduces its affinity to serum protein

261 he advances in bottom-up nanoengineering and surface chemistry, reductionist functionalization approa

262 noparticles, spatial control of nanoparticle surface chemistry remains a major challenge.

263 Aqueous-phase and surface chemistry resulted in elevated levels of gas-pha

264 Non-adiabaticity in the surface chemistry results in the creation of electron-ho

265 he proof-of-concept study, we demonstrated a surface-chemistry strategy to achieve metallic Ni(OH)2 n

266 st-principles calculations, we find that the surface chemistry strongly affects Fermi level of MXenes

267 the first time, recent advances in nanoscale surface chemistry, surface science, DFT, adsorption calo

268 The possibility of performing surface chemistry tailoring with SAMs constitutes a vers

269 ve been produced with nonthermal plasmas and surface chemistries that have been developed, and provid

270 clusters (MMNCs) offer unique and tailorable surface chemistries that hold great potential for numero

271 cle library of three different sizes and two surface chemistries that include anionic citrate and the

272 forms through a combination of solution and surface chemistries that results in the formation of a b

273 approaches have focused on developing unique surface chemistry that can exchange bulky ligands with s

274 This paper describes the changes in surface chemistry that occur in oleate-capped CdS quantu

275 Owing to unique surface chemistry, the T-GR demonstrates an excellent en

276 ls with precisely engineered composition and surface chemistry, their combination and consolidation i

277 By making use of simple surface chemistry, these two effects can be synchronized

278 ve as excellent alternatives to standard PEG surface chemistries to achieve mucus penetration and add

279 e probe molecule allowing the differences in surface chemistry to be mapped by NMR spectroscopy.

280 Therefore, we introduce the surface chemistry to bifunctionalize AFM tips with the n

281 Ants exploit differences in body surface chemistry to distinguish nestmates from colony i

282 By controlling the surface chemistry to enable strong PM adhesion and also

283 Passive targeting utilizes shape, size, and surface chemistry to increase particle circulation and t

284 an locate SERS hot spots but also modify the surface chemistry to realize selective enhancement Raman

285 -out for protein adsorption, we optimize the surface chemistry to yield a mixed charge surface which

286 tative experiments on how solution-phase and surface chemistry together produce biologically relevant

287 The change in local surface chemistry via formation of surface oxygen relate

288 s the characterization of the nanomaterial's surface chemistry via the molecular interactions affecti

289 elds a highly strained bicyclic olefin whose surface chemistry was hitherto unknown.

290 Surface chemistry was selected to nonspecifically adsorb

291 ing FN structure and dynamics through tuning surface chemistry, we found that as the conformational a

292 adability in vivo, as well as their flexible surface chemistry, which allows drug loading, functional

293 loyed to reveal changes in the structure and surface chemistry while simultaneously introducing defec

294 in TOF-SIMS data analysis enable correlating surface chemistry with biological response.

295 ity for both droplet-based methods depend on surface chemistry, with glass slides modified with 3-Gly

296 us closer to molecular level programming of surface chemistry, with promising applications such as 3

297 ptamer interactions based on silane-coupling surface chemistry, with thrombin concentrations ranging

298 Chlorination also altered N-CNT surface chemistry, with X-ray photoelectron spectroscopy

299 Important points of study were surface chemistries within poly(methyl methacrylate) (PM

300 ) additives has been eliminated by utilizing surface chemistry within the device channels to control