ライフサイエンスコーパス: surface property

1 ilm relaxation dynamics and is a solely free surface property.

2 due to independent mechanisms that tune the surface properties.

3 e of control over pore sizes, dimensions and surface properties.

4 sively utilized to explore various nanoscale surface properties.

5 n to modulate both the physical and chemical surface properties.

6 e, chemical composition, cargo, modulus, and surface properties.

7 robes typically limits these measurements to surface properties.

8 ion modifies the overall chemokine shape and surface properties.

9 lization process to characterize the gold WE surface properties.

10 erformance flexible electrodes with tailored surface properties.

11 ns in these ORFs confer changes in bacterial surface properties.

12 y desired materials, due to their beneficial surface properties.

13 kes advantage of hydrophobic and hydrophilic surface properties.

14 pulsion and possibly other changes in oocyst surface properties.

15 rstand their unique nature is to study their surface properties.

16 e, aggregation, morphology, dissolution, and surface properties.

17 n their chemical composition, dimension, and surface properties.

18 assumed to be neutral in calculations of the surface properties.

19 ly of effects on adhesive and other material surface properties.

20 silica microbeads having different sizes and surface properties.

21 sorb onto the nanowire surface and alter the surface properties.

22 al morphology and spore size, structure, and surface properties.

23 -stick events, which carry information about surface properties.

24 r coarser to reflect large-scale texture and surface properties.

25 e in surface hydrophobicity and affected the surface properties.

26 s offering high-resolution information about surface properties.

27 herical particles with anisotropic phase and surface properties.

28 ates the ability to efficiently control pore surface properties.

29 ed for fibrin proliferation as a function of surface properties.

30 ong-lived intrinsic variability in bacterial surface properties.

31 nities but instead by fold and electrostatic surface properties.

32 ssesses a conserved active site but distinct surface properties.

33 ght is not strongly modified by the objects' surface properties.

34 motion of embedded particles with controlled surface properties.

35 ach AC-NP formulation is dependent on the NP surface properties.

36 BoNT/A reveals striking differences in their surface properties.

37 synthetic cages with full control over their surface properties.

38 sfully linked to differences in their capsid surface properties.

39 at is sensitive to ligand-induced changes in surface properties.

40 size and optimal shape provides exceptional surface properties.

41 e voltage applied on the electrode or by the surface properties.

42 y biological chemistry and modulate physical surface properties.

43 monic response is strongly dictated by their surface properties.

44 e potential and EDLC by chemically modifying surface properties.

45 ry polymers may generate reversibly tuneable surface properties.

46 which is attributed to an improvement in its surface properties.

47 d and lead to continuously, slightly varying surface properties.

48 major focus due to their tunable optical and surface properties.

49 gy, crystallinity, defect concentration, and surface properties.

50 or conformation resembles Ub but has altered surface properties.

51 t from distinct differences in electrostatic surface properties; additional predicted positively char

52 These surface properties affect the ability to chemically func

53 smon resonance and analyse these in terms of surface properties, amino-acid conservation and mutation

54 gluconeogenesis, glycolysis, motility, cell surface properties and adherence are modulated by csrA i

55 ospholipid composition can modulate membrane surface properties and affect catalytically important mo

56 The surface properties and conservation of the Nup133 beta-p

57 anges in CCL3 N termini profoundly alter its surface properties and dimer-dimer interactions to affec

58 Understanding the surface properties and dopant distribution will be criti

59 nowires, but it has not been used to measure surface properties and dopant distributions, despite the

60 that naturally occurring sEPS can modify the surface properties and fate of nTiO2 in natural waters,

61 oduced by freshwater and marine algae on the surface properties and fate of three commercial TiO2 nan

62 cationic, and nonionic polymers) on membrane surface properties and fouling.

63 sI domains and SpaI differ strongly in their surface properties and function.

64 e CSMA and CSMB genes play in modulating the surface properties and immune interactions of A. fumigat

65 ering materials reveal that knowledge of the surface properties and impact conditions can be used to

66 he dependence of protein mobility on protein surface properties and ionic strength.

67 0-like cytokines by sequence similarity, its surface properties and its distinctive disulfide arrange

68 However, the translocon, via its surface properties and its variable diameter, shifts the

69 The surface properties and known complexes of nitrogenase co

70 structure content, amino acid propensities, surface properties and ligands, we describe each enzyme

71 -structure content, amino acid propensities, surface properties and ligands.

72 ed the adsorption of proteins with different surface properties and lipid vesicles with different pha

73 In addition, Aqy1p and Aqy2p can affect cell surface properties and may provide an advantage by dispe

74 enous muramidase activity affecting the cell-surface properties and morphology of this important path

75 very of a family of Kuiper belt objects with surface properties and orbits that are nearly identical

76 Finally, all these surface properties and performances were significantly a

77 physicochemical properties, including size, surface properties and pH sensitive behavior, regardless

78 lipid binding activity is modulated by lipid surface properties and protein tertiary structure.

79 s of structural impurities such as Al on the surface properties and reactivity of ferrihydrite.

80 tion method is insensitive to the structure, surface properties and rotation state of the asteroid.

81 The control of surface properties and spatial presentation of functiona

82 ering deeper knowledge of the site location, surface properties and stability to aid the design of ne

83 hods, semiconductor nanowires offer superior surface properties and stronger optical confinement.

84 To elucidate the relation between surface properties and surface reactivity, the physical

85 escribe a computational approach whereby the surface properties and symmetry of a targeted surface de

86 he C1 domain acts as a sensor of the bilayer surface properties and that its conformational response

87 neered applications, the effect of electrode surface properties and the magnitude and polarity of app

88 oatings are used to modulate the nanocrystal surface properties and to bioactivate the nanoparticles.

89 ning SiO2 nanoparticles (NPs) with different surface properties and two multiwalled carbon nanotube (

90 Surface property and enzymatic reactivity differences be

91 re mainly attributed to the superhydrophilic surface property and excessive nanoscale nucleation site

92 m in size, including plastics with differing surface properties, and tested the impact of microplasti

93 on albedo, eco-physiological and aerodynamic surface properties, and turbulent energy fluxes of a low

94 The asteroid's surface properties are consistent with a regolith having

95 lationships among geometries, materials, and surface properties are discussed, especially in the cont

96 nvasion ligand in Plasmodium falciparum--its surface properties are distinct and provide a possible m

97 harge products in Li-oxygen batteries, their surface properties are expected to play a key role in un

98 Plasma lipoprotein surface properties are important but poorly understood d

99 However, nanoparticle size, shape, and surface properties are known to affect nanoparticle-cell

100 irable monolayer bimetallic systems when the surface properties are not a linear function of the pare

101 e worked under conditions where the membrane surface properties are not expected to change.

102 the thickness of the silicate layer and its surface properties are precisely controlled.

103 Our data suggest that although several surface properties are remarkably similar between the tw

104 c and hydrophobic while its superhydrophilic surface properties are restored upon hydrolysis.

105 These surface properties arise from proton disorder and the re

106 The molecular hashkey represents molecular surface properties as a linear array of pairwise surface

107 pod, most likely through the control of cell-surface properties as shown by cell-cell sorting analyse

108 complementary target DNA yields a change in surface properties as the two DNA strands hybridize.

109 ion techniques detecting the bulk nature and surface properties as well as the effects of various fun

110 a multifunctional regulator, affecting cell surface properties as well as the expression of NorA and

111 downstream of vhnf1 to repress r4-like cell-surface properties, as determined by an 'Eph-ephrin code

112 PS-capped selenium nanoparticles had similar surface properties, as shown by zeta-potential versus pH

113 res by controlling their structure and their surface properties at a nanoscale level makes them extre

114 xhibits high sensitivity to small changes in surface properties, because of the constitution of speci

115 ks were distinct, suggesting a difference in surface properties between populations of the HGE agent

116 2D FDS showed to be sensitive to changes in surface properties between ZnO NPs synthesized by differ

117 layers (monolayers) as used for engineering surface properties, biosensing, nanomedicine, and smart

118 loxane substrates fabricated to have similar surface properties but a 10-fold difference in Young's m

119 erent resist and stamp materials of distinct surface properties by AFM and molecularly imprinted sorb

120 Tailoring the surface properties by varying the chemistry and roughnes

121 Surface properties can be mapped with high spatial resol

122 ggest that mineral surfaces with appropriate surface properties can be very effective in concentratin

123 provide a conceptual basis for how locomotor surface properties can challenge established rules for t

124 (LC) assembly is exceptionally sensitive to surface properties, capable of transducing nanoscale int

125 understanding of the redox reaction-induced surface property changes of CeO2 NPs and their transport

126 AgNPs differentially modified particle size, surface properties (charge, plasmonic spectra), and ion

127 ial of these techniques for building complex surface property/chemistry models.

128 rolyzed photoresist films (PPF) show unusual surface properties compared to other carbon electrodes.

129 mology modeling exhibit atypical hydrophobic surface properties, compared with the already known vert

130 pliance of the substrate while holding other surface properties constant.

131 t by which a functional underestimates these surface properties correlates with the extent to which i

132 m multilayer structures demonstrated various surface properties, depending on their conditions of fab

133 Surface properties, dispersion state, and sorption behav

134 Cell surface properties (e.g., zeta potential) were determine

135 Trends in satellite-derived cloud and surface properties for 1982 to 1999 show that the Arctic

136 nctional groups are attractive for modifying surface properties for a variety of applications.

137 le, enabling new opportunities for enhancing surface properties for catalysis and other important tec

138 he adhesive coated surface proposes the best surface properties for efficient colorimetric microarray

139 ostructured gate dielectric, indicating good surface properties for pentacene film growth.

140 unctionalization approaches on modifying the surface properties for specific applications in catalysi

141 We observed a marked change in overall surface properties for surface tensions >10 mN/m, indica

142 The bottleneck of unknown surface properties from proprietary resin use in fabrica

143 xposed particles show different chemical and surface properties from the unexposed particles, while t

144 vity and understanding and controlling their surface properties have become critical.

145 DCFC systems, in terms of crystal structure, surface properties, impurities and particle size, is als

146 ta call for a reconsideration of the role of surface properties in biological filtration and predator

147 could significantly improve the accuracy of surface properties in comparative models.

148 cate PDMS microfluidic devices with distinct surface properties in different regions or channels.

149 P) has been implicated in regulation of cell surface properties in several bacterial species, includi

150 Selective modification of titanium surface properties in various regions of an implant may

151 lengths longer than 15 mum, even though this surface property in this far-IR region has a direct impa

152 lyte, which represents a key physicochemical surface property in various fields ranging from electroc

153 been made to achieve the control of bulk and surface properties including the wettability, acid-base

154 Surface properties including wettability, surface potent

155 icity is closely correlated with quantum dot surface properties (including shell, ligand and surface

156 These shifts in land surface properties increase latent at the expense of sen

157 We summarize how these surface properties influence oral biofilm formation, and

158 This redox-linked change in surface properties is likely to be responsible for diffe

159 ting that persistent alterations in particle surface properties may be responsible for intrinsic spee

160 Ribosome surface properties may thus limit the composition of the

161 Here, we combine theory, surface property measurements, and amyloid fibrillogenes

162 We found that surface properties near the catalytic copper, i.e. side

163 However, uncontrollable surface properties of a fabricated nanopore cause irregu

164 effect of PEG on the internal structure and surface properties of CL-DNA complexes is essential in d

165 It is demonstrated that the physical surface properties of conducting polymer microcups can b

166 Together, the invasive and cell surface properties of cytotrophoblasts enable them to fo

167 mer "liftoff" arrays combine the hydrophobic surface properties of di-p-xylylene (Parylene) with phot

168 considered to probe the impact of changes in surface properties of dispersed fullerenes (nC60) on the

169 a novel microfluidic strategy to manipulate surface properties of enclosed microchannels and create

170 ferroelectric films; however, the intrinsic surface properties of ferroelectric oxides have been lar

171 The surface properties of GO nanoparticles and quartz sand w

172 However, the surface properties of HDL and other lipoproteins are poo

173 The surface properties of high-density lipoproteins (HDLs) a

174 ive molecular characterization of the unique surface properties of LDs and suggest how the molecular

175 eating on the structure and subsequently the surface properties of LTP1, a nonspecific lipid transfer

176 Analysis of the molecular surface properties of macins allowed confirmation of the

177 ialkoxysilanes are widely used to modify the surface properties of materials and devices.

178 The unique surface properties of materials and interfaces generated

179 ted to chemical composition and physical and surface properties of materials.

180 rom the ability of TSP2 to modulate the cell surface properties of mesenchymal cells, and thus, to af

181 Modification of the surface properties of metals without affecting their bul

182 lead to further development in enhancing the surface properties of metals.

183 Cer and FC changed the surface properties of mixed MLF in a way that implied th

184 n widely used to tailor the size, shape, and surface properties of nanocrystals and control the pore

185 gn can be used to modulate the electrostatic surface properties of nanocrystals, presenting an opport

186 position, size, shape, crystal structure and surface properties of nanocrystals, thus setting the sta

187 uences can mediate the control of shapes and surface properties of nanoparticles.

188 sionalities, intrinsic defect chemistry, and surface properties of nanostructures.

189 ns in the Gibbs ensemble and compared to the surface properties of neat water and 1-butanol liquids.

190 tions did not alter the overall structure or surface properties of NT-Als3.

191 be more pronounced as the differences in the surface properties of P and PL become more significant.

192 a marked effect of haemoglobin C on the cell-surface properties of P. falciparum-infected erythrocyte

193 Although it is well-known that the surface properties of PDMS can be modified by anionic su

194 aminants from bulk PDMS and for changing the surface properties of PDMS.

195 of plasma-based technologies for tuning the surface properties of polymers, principally through free

196 tigated the photosensitization, optical, and surface properties of pSi as a function of time in aqueo

197 The surface properties of PtM (M = Co, Ni, Fe) polycrystalli

198 Despite their largely conserved fold, surface properties of PTPs are strikingly diverse.

199 This work describes the electrical surface properties of SEBS block copolymers using curren

200 s a second messenger that modulates the cell surface properties of several microorganisms.

201 the understanding of fundamental physics and surface properties of silicon nanocrystals.

202 ects of size, morphology and physicochemical surface properties of six marine phages and two coliphag

203 simple but powerful approach for probing the surface properties of small-size bioobjects, opening a r

204 Also included are methods for altering the surface properties of SU-8 and introducing functional gr

205 These differences arise mainly because the surface properties of submicron particles dominate their

206 Homology modelling suggests that the surface properties of TB3 domains from different LTBP is

207 ellipsometry was used to measure optical and surface properties of the air-dried and hydrated materia

208 izations define adaptive macroscopic wetting surface properties of the amphiphilic Y-shaped brushes.

209 -Baxter wetting on the arrays, including the surface properties of the array components as well as th

210 ns depend on the spin axis, composition, and surface properties of the asteroid, so that refining the

211 sent study indicates that the design and the surface properties of the AuNRs enhances neural differen

212 There is no apparent pseudo-symmetry in the surface properties of the BtuF domains flanking its B12

213 This reduces the dependence on the surface properties of the catalytic substrate, improving

214 this mutation is a subtle one, affecting the surface properties of the crystallin molecule rather tha

215 pectroscopy has been used to investigate the surface properties of the DLC films including the sp(3)/

216 mples crystal packing space by modifying the surface properties of the enzyme.

217 Alterations in the cell surface properties of the EPS-specific mutants were demo

218 ion in the deposited glasses in terms of the surface properties of the equilibrium liquid.

219 and composition of the palladium films, the surface properties of the film become more receptive tow

220 The physicochemical surface properties of the foam were characterized using

221 Understanding the surface properties of the human opportunistic pathogen A

222 To provide an overview of the surface properties of the interfaces formed by the compl

223 e elaborate tuning of the physiochemical and surface properties of the IONPs.

224 However, it is not clear how the local surface properties of the membrane, such as membrane ten

225 ccurate characterization of the viscoelastic surface properties of the microbubbles, but methods for

226 Examination of the surface properties of the N-terminus-binding pocket indi

227 is suggested that the important role of the surface properties of the oxide support in these polymer

228 y serve as pre-treating agents to modify the surface properties of the particle stabilizer, and not b

229 ency and amplitude of the electric field and surface properties of the particles.

230 to characterize the geometry, stiffness, and surface properties of the pillars that favor the adhesiv

231 The surface properties of the plant tissue, nutrient and wat

232 polystyrene particle (ANOVA, P < 0.01), and surface properties of the plastic, with aminated particl

233 nt-exposed histidine residues shows that the surface properties of the protein change with pH, sugges

234 ation of LTP1 is important in optimizing the surface properties of the protein that are essential in

235 ffect of the changes in the structure on the surface properties of the protein was also measured.

236 h which spores germinate but also change the surface properties of the spore, which, in turn, may imp

237 The measured surface properties of the two FIB strains supported the

238 d its effect at very low molar ratios on the surface properties of the zwitterionic phospholipid 1,2-

239 The distinct surface properties of these compounds may explain observ

240 strategies to rapidly and easily tailor the surface properties of these devices.

241 rough the introduction of carbohydrates, the surface properties of these graphitic carbon nanostructu

242 f Bacillus pumilus, reveals diversity in the surface properties of these mutants.

243 Hence, the surface properties of UCNPs must be well designed and ch

244 ess made toward controlling and altering the surface properties of ZnO, and to bring attention to the

245 group can tune the size, shape, and internal surface property of a MOF for a targeted application.

246 and (ii) using them to sense changes in the surface property of the target in cells.

247 the understanding of the effects of membrane surface properties on 5-LO-membrane interactions and the

248 It is believed that mucoadhesive surface properties on particles delivered to the gastroi

249 oped recently, the impact of physicochemical surface properties on the hydration layer remains contro

250 re, we address the impact of physicochemical surface properties on the hydration shell by a systemati

251 is necessary to identify the influence of NM surface properties on their toxicity, and determine how

252 ears and can be chemically modified to alter surface properties or to immobilize growth factors.

253 exhibit heterogeneity in size, composition, surface property, or morphology.

254 as been explored to control and regulate its surface properties, particularly at heterointerfaces in

255 n the two isolates indicating that bacterial surface properties play a role in how biochar affects E.

256 Electrophoretic mobility is a heterogeneous surface property reflective of mitochondrial surface com

257 h ethidium bromide transport and normal cell surface properties require functional P55 and LprG, as n

258 of Pax6 is the continual regulation of cell surface properties responsible for both cellular identit

259 layer approach is tailored to yield specific surface properties, resulting in a durable, functional c

260 The analysis of various surface properties revealed that roughness and hydrophil

261 reciprocal relationship between the membrane surface properties, strength of membrane binding of PLA2

262 ilitate DNA packaging, as well as to mediate surface properties such as cell attachment and infection

263 nd thermal stability of these materials with surface properties such as chemical recognition or react

264 ux (CHF) has focused on altering the boiling surface properties such as its nucleation site density,

265 bonus, the resultant material shows enhanced surface properties such as markedly improved organic dye

266 Surface properties such as micelle formation, critical a

267 vironments typically have adverse effects on surface properties such as optical transmittance, surfac

268 nds, intrinsic surface defects, and superior surface properties, such as hydrophilicity, high surface

269 PDMS by vesicle fusion bring about favorable surface properties, such as improved wettability and pro

270 Land surface properties, such as vegetation cover and soil mo

271 Further analysis of the surface properties suggests a probable binding orientati

272 able to provide more detailed information on surface properties than ever before, thanks to the simul

273 ognition domain because it lacks many of the surface properties that are present in other pleckstrin

274 , implying that these two isolates have cell surface properties that differ considerably.

275 Thus differences in the surface properties that regulate lipolytic reactivity ar

276 Amphiphilicity is a surface property that has yet to be explored for the nob

277 Changing atmospheric conditions, surface properties, the complexity of icing physics, and

278 We hypothesize that, by altering lung airway surface properties through an inhaled nontoxic aerosol,

279 s engineered with optimal sizes, shapes, and surface properties to increase their solubility, prolong

280 ration range from those associated with cell-surface properties to others which affect mitochondrial

281 le to use UV grafting to impart a variety of surface properties to PDMS microfluidics devices.

282 of the sigma(X) regulon serves to alter cell surface properties to provide protection against antimic

283 erial YBa2Cu4O8, which reveals similar Fermi surface properties to YBa2Cu3(6+delta), despite the nono

284 tivity, long-term stability, and antifouling surface property toward ACh and its oxidation product.

285 to gain detailed insights into the nanoscale surface properties (ultrastructure, hydrophobicity) and

286 en attachment efficiency and any single-cell surface property was identified.

287 ut mice than in wild-type mice, whereas this surface property was unaffected in cyclooxygenase-2 knoc

288 The surface properties were characterized using contact angl

289 Surface properties were evaluated by measuring equilibri

290 y on its composition, texture, structure and surface properties, which have to be precisely controlle

291 grees 's, in the same scaffold with the same surface properties, will find wide applications in chemi

292 per describes VASP-E (Volumetric Analysis of Surface Properties with Electrostatics), a novel volumet

293 ch therefore is able to link microscale cell-surface properties with macroscale bacterial transport b

294 ese land cover changes alter landscape-scale surface properties with potentially large, however, stil

295 ic structure, providing a flexible design of surface properties with this exciting new class of diamo

296 ontaining polystyrene particles of different surface properties with various proteins (bovine serum a

297 with similar orbits and, frequently, similar surface properties, with each family being the remnant o

298 If the surface properties within the pit chamber are similar to

299 tional transitions to macroscopic changes in surface properties without altering the chemical identit

300 ambient photo-modification of the chitosans' surface property without significant changes in size and