ライフサイエンスコーパス: pore size

1 uit additional prepore oligomers to grow the pore size.

2 selectivity of CFTR and ANO1 by changing the pore size.

3 thout the need for subnanometer control over pore size.

4 and the glycine receptor (GlyR), by changing pore size.

5 gth of the binding and the ECM stiffness and pore size.

6 leased gradually, in a manner constrained by pore size.

7 tility stalls 3D migration regardless of ECM pore size.

8 eractions and possibly masking the effect of pore size.

9 ng polymer molecular weight and reduction in pore size.

10 quilibrium size before reaching the critical pore size.

11 cell parameters, SiO distance and especially pore size.

12 sed data can be used to estimate the network pore size.

13 nd afford a higher surface area and a larger pore size.

14 rganic framework with narrow (1-1.5 nm) cage/pore size.

15 a function of the applied potential and the pore size.

16 rior for molecules and ions smaller than the pore size.

17 ore character associated with differences in pore size.

18 highest on Orai1-V102C with an intermediate pore size.

19 ion occurs in the aquitard despite the small pore sizes.

20 MCF-10A cells through filters with different pore sizes.

21 ubes provided a TC/SG composite with reduced pore sizes.

22 area up to 370 m(2)/g with a broad range of pore sizes.

23 sorption at different process conditions and pore sizes.

24 ed finger-like pore morphologies and varying pore sizes.

25 al concentrations, ambient temperatures, and pore sizes.

26 full-scale membrane bioreactor (MBR; nominal pore size 0.04 mum): (i) attachment of virus to mixed li

27 SSZ-24, MCM-41, and SBA-15) as a function of pore size (0.8 nm to 20.0 nm).

28 esoporous materials, as characterized by the pores sizing 1.2 nm and 12.2 nm, respectively.

29 ived carbon (CDC) with two different average pore sizes (1 and 0.65 nm), from neat and solvated 1-Eth

30 In meso-porous materials, with pore sizes 2 nm < d(p) < 50 nm, there is a central core

31 largest BET surface area (3411 m(2) g(-1)), pore size (20.5x20.5x37.4 A) and void volume (78.5%) of

32 A-200), is reported with ultrafine tuning of pore size (3.4 A) to effectively block ethylene (C2 H4 )

33 ated through nylon mesh filters of different pore sizes (40 to 10 mum).

34 Changes in pore size affected not only the energy barriers of size

35 ith an event size of the order of an average pore size, again much smaller than the large bursts seen

36 ication by X-ray diffraction and microscopy, pore size analysis and activity assessment by IR spectro

37 us water transport passageway with a defined pore size and (2) the incorporation of polyethylenimine

38 ever, the selectivity of a material with the pore size and chemistry that already maximizes selectivi

39 rous strut orientation, variable inter-strut pore size and controlled film width (via layering).

40 s via RCM were accelerated by increasing the pore size and decreasing the catalyst loading density wh

41 ayers show a large distribution in porosity, pore size and depth along the radius of the samples.

42 With extraordinarily large pore size and excellent chemical stability, PCN-333 may

43 d in a decrease and then an increase in both pore size and fiber alignment, which both correlated sig

44 dy, we used hydrogen peroxide to control the pore size and fibre crossing density of the ESM.

45 and compositional changes including reduced pore size and fluid content.

46 The Y67A mutant enlarged the pore size and further decreased the charge selectivity d

47 arying the properties of the membrane (e.g., pore size and hydrophobicity).

48 osity with the electrode having the smallest pore size and largest surface area, providing near ideal

49 hanced by optimizing the support in terms of pore size and mechanical strength and the TFC layer with

50 Differences in pore size and other features were interpreted as an evol

51 e properties of nanocrystals and control the pore size and phases of mesoporous frameworks, the use o

52 ranine and viologen to reversibly modify the pore size and philicity.

53 Synthetic control over pore size and pore connectivity is the crowning achievem

54 racterized by a regular porosity in terms of pore size and pore network arrangement, ordered mesoporo

55 ly localized transient laser heating enables pore size and pore size distribution control in all-orga

56 pbz-MOF-1 is highly porous, with associated pore size and pore volume of 13 A and 0.99 cm(3) g(-1),

57 meance enhancement increased with increasing pore size and porosity of the MOF used as filler.

58 Based on the pore size and resealing time, we predict that few DNA pl

59 n of increasing compaction due to changes in pore size and structure, hydration energy, and overlappi

60 We also explored the impacts of pore size and temperature on the surface tension and con

61 mplying that the material comprises a single pore size and that the porous material is fully saturate

62 the lumen a function of the substrate entry pore size and the bulkiness of the gating residues.

63 can be controlled by choice of the membrane pore size and the chemistry.

64 gradation of pSiO2 increased with increasing pore size and the degradation of pSiO2 was approximately

65 0.0001) and a direct correlation between the pore size and the drug levels in the living eye vitreous

66 hese nets is tailored by synergy between the pore size and the strong electrostatics afforded by the

67 Pore size and volume are the structural characteristics

68 essing of the POP dramatically increased the pore size and volume, allowing for significantly higher

69 framework (MOF) research is the expansion of pore size and volume.

70 ent migration declined as linear function of pore size and with deformation of the nucleus, with arre

71 ce area and pore volume, uniform and tunable pore sizes and chemical modifiability are the reasons fo

72 In this study, the effect of different pore sizes and different mesh module configurations on t

73 hermoelectric materials with well-controlled pore sizes and distributions to suppress thermal conduct

74 r(2) > 0.95 for diverse ECMs with different pore sizes and stiffness.

75 e in relation to membrane surface charge and pore size) and (ii) concentration polarization, dependin

76 we examined the impact of filters (types and pore sizes) and physiochemical properties of surface wat

77 Other features such as thickness, pore size, and disorder are also found to generally agre

78 high porosity, low tortuosity, large surface pore size, and high surface hydrophobicity.

79 sign such as particle-particle interactions, pore size, and macromolecular accessibility can be tuned

80 ighly adjustable in terms of its dimensions, pore size, and materials.

81 by molecular size of diffusive species, clay pore size, and organic surfactant loading.

82 ge surface area, high crystallinity, tunable pore size, and unique molecular architecture.

83 y framework, BPP-7, features slightly larger pore sizes, and the resulting improvement in uptake kine

84 Crystals larger than the pore size are retained and arrange themselves according

85 " N species, large surface area, and similar pore size as electrolyte ions endow the nitrogen-doped P

86 howed high separation efficiency (99%), with pore size as high as 150 microm, whereas ZnO coated surf

87 prepare a series of polyimide (PI) COFs with pore size as large as 42 x 53 A(2), which is among the l

88 free-flow zone electrophoresis with tunable pore size as well as surface charge polarity.

89 is because of the improved surface area and pore sizes as well as altered chemical compositions.

90 imize the free energy of the system for each pore size, as indicated by trends in the enthalpy of int

91 Na(+) permeability, Cl(-) permeability, and pore size back to wild-type.

92 dates are pellets of MCM-41 and aerogel with pore sizes between 10 and 30 nm, possessing hydrophobic

93 metric evaluation of the nanochannels (20 nm pore sized) blockage due to the immunocomplex formation.

94 anocapsules retain molecules larger than the pore size but provide ultrafast access to their interior

95 all thickness of the layer with the smallest pore size called the top layer.

96 Through our approach, the effective pore size can be reduced through the immobilization of m

97 h conversion rates and yields dependent upon pore size, catalyst loading density, and linker length.

98 Pore size change affects the energy barriers of ion dehy

99 ing flexibility, depending on the material's pore size characteristics.

100 bally optimal material will have the optimal pore size/chemistry and minimal intrinsic flexibility ev

101 Pore size control in this family of dia nets was exerted

102 General aspects concerning pore size control, atomic scale crystallinity, and phase

103 cursor solution to eliminate the interfacial pore-size control issues that arise when a polymerizing

104 , organic or even protein-based which offers pore-size control, catalytic activity or permeation regu

105 tes, 2D and 3D porous networks with tuneable pore sizes could be prepared from various materials, for

106 ed as regulators of cell motility, including pore size, crosslink density, structural organization, a

107 Such bio-inspired materials, whose pore sizes decrease across multiple scales and finally t

108 We find that the pore size decreases with the square root of the concentr

109 n a circular pore increases exponentially as pore size decreases.

110 of the three-dimensional distribution of the pore sizes, defined as the diameters of the largest sphe

111 of the sap and features of the BPM, such as pore size, density of chargeable sites, and their dissoc

112 an important application, we investigate the pore size dependence of collagen and fibrin networks on

113 10% for np-Au with coarser pores revealing a pore-size dependence of sensor performance in biofouling

114 uring radiation, and their shrinkage rate is pore size dependent.

115 Here we visualize within a living cell the pore-size dependent deformation of a specific locus engi

116 rial properties, including porosity, average pore size, dielectric constant, and plasmonic response.

117 uctures offer a great degree of control over pore sizes, dimensions and surface properties.

118 99.6%), light weight (5 mg/cm(3)) and narrow pore size distribution ( 2 to 5 nm), the ECF anode exhib

119 n but opaque to visible light because of the pore size distribution (50 to 1000 nanometers).

120 s and computer modeling study, together with pore size distribution analysis confirm that each of the

121 ty density function (PDF) description of the pore size distribution and classical filtration theory.

122 Analyses of adsorbent pore size distribution and surface chemistry confirmed t

123 ransient laser heating enables pore size and pore size distribution control in all-organic and highly

124 The hierarchical tetramodal pore size distribution influences the properties of alph

125 , alpha-MnO2, with a hierarchical tetramodal pore size distribution spanning the micro-, meso- and ma

126 abricated hollow fiber membrane has a narrow pore size distribution with a molecular weight cutoff (M

127 Physical parameters such as pore size distribution, application of these materials t

128 greement between MICP and adsorption-derived pore size distribution, especially for pores having a ra

129 ic imaging resolution including porosity and pore size distribution, except of an increase of deposit

130 icroscopic characteristics of the substrate (pore size distribution, porosity, permeability, and depo

131 ted shales is performed, including porosity, pore size distribution, specific surface area and pore c

132 pth gradient but has a reverse effect on the pore size distribution.

133 We present a numerical method to extract the pore sizes distribution of the porous structure directly

134 The tunable pore-size distribution and high pore volume of CDC allow

135 ons during CO2 sequestration will change the pore-size distribution and pore surface characteristics,

136 The effect seems to be enhanced by a narrow pore-size distribution centered at 1.2 nm, approximately

137 These results suggest that the pore-size distribution in which a precipitation reaction

138 per using the manufacturer's data, published pore-size distribution measurements, and the fluid's pro

139 lume) show different results of porosity and pore-size distribution obtained from the MICP method (qu

140 ver, SANS and LPNP methods exhibit a similar pore-size distribution, and both methods (in measuring t

141 Applying this straightforward physics to pore size distributions for the mixed-pore grainstones r

142 Results include (1) material porosity and pore size distributions, (2) effective diffusion coeffic

143 n amine-efficiency (CO2/N binding ratio) and pore size distributions, and points to a trade-off betwe

144 They possess ordered pore structures, narrow pore size distributions, large surface areas, high stabi

145 agnetic resonance (NMR) can characterize the pore size distributions, porosity, and permeability of s

146 compute small-angle scattering intensities, pore size distributions, specific surface area, local de

147 ase morphologies having well-defined, narrow pore size distributions.

148 as for graphene and 25 MOFs having different pore-size distributions.

149 S) enabled continuous in situ control of the pore size during experiments.

150 vides an effective means for controlling the pore size, electronic conductivity, and loading mass of

151 This large pore size enables the inclusion of electron-conducting s

152 The bias of the pore size estimate due to the missing fibers can be corr

153 This was further corroborated with pore-size estimates utilizing hindered-transport theory,

154 n established from the temporal component of pore size evolution as characterized by in situ PALS.

155 s of such structural collapse with regard to pore size evolution during degradation are currently unk

156 lsive surface forces combined with selective pore size exclusion from the pores of denser, more devel

157 uclear import kinetics, although the nuclear pore-size exclusion barrier was maintained.

158 of the active material above the membrane's pore-size exclusion limit.

159 d strong dependence of transport kinetics on pore size: fast regular transport in large pores (> 5 nm

160 lets separated from lymphocytes by a 0.4-mum pore size filter.

161 ozonation of effluent filtered with smaller pore size filters, indicating that particles in this ran

162 dary effluent was filtered through different pore-size filters and ozonated at various ozone doses.

163 be captured using particular combinations of pore size, filtration parameters, and antibody functiona

164 yers demonstrated the critical role of their pore size for selective function of the DGT devices.

165 thought to be related to the large range of pore sizes found in FCC particles.

166 ching parameters allowed control of the nano-pore size from 15nm to 95nm.

167 lvation increased when decreasing the carbon pore size (from 1 down to 0.65 nm).

168 porous materials, but it is a combination of pore size, geometry, and functional group that leads to

169 e tuned potential, we studied the effects of pore size, geometry, and temperature on the wetting of m

170 bilization, to increase the MOF porosity and pore size, giving rise to hierarchical-pore architecture

171 At pore sizes greater than 100 nm, protein loading generall

172 We show that the effective pore size, hydrophilicity, and organophilicity of ZIFs c

173 able tunability of properties like effective pore size, hydrophobicity, and organophilicity.

174 on of contact angle and surface tension with pore size improves the agreement between MICP and adsorp

175 ase and decrease their volume to control the pore size in response to environmental cues.

176 Increasing the pore size in the glass frits from the <10 nm into the 1

177 aterials are characterized by a controllable pore size in the nanometer range, high mechanical, therm

178 ionic organic networks (NIONs), here with a pore size in the range from sub-1 nm to 100 nm, we obser

179 a crystal engineering approach to tuning of pore-size in a coordination network, [Cu(quinoline-5-car

180 rameters have been studied including cut-off pore size, interstitial fluid pressure, and tumor tissue

181 In conjunction with a tight control over pore sizes, inverse opal scaffolds have found widespread

182 showed that this transition occurs when the pore size is <3x the maximum of molecular dimensions.

183 ific surface area and/or to manipulate their pore size is a common practice to enhance their adsorpti

184 The tPTP pore size is much smaller than for permanent mPTP, as ne

185 When the pore size is on the nm scale, as the porosity increases,

186 icant impact on diffusional transport as the pore size is reduced to the nanoscale.

187 Thanks to small pore sizes, large internal cavity and sufficient dynamic

188 Main structural parameters (pore size, layer thickness, morphology and nanograins si

189 e dilution, rinsing protocol, flow rate, and pore size, leading to >80% for the recovery of spiked ca

190 We then determine pore size limitations using fluorescently labelled model

191 Current microporous membranes [pore size < 1 nanometer (nm)], however, are usually rela

192 such as polymers of intrinsic microporosity (pore size<2 nm) are especially interesting in being solu

193 investigated the effect of changing porosity/pore size, material thickness, and chamber fluid mechani

194 The membrane potential method used for pore size measurement is underlined as the most appropri

195 Here, using a unique large pore-sized membrane microdialysis, we characterized solu

196 crystalline, thermally controlled monomodal pore size mesoporous materials.

197 control of particle size, size distribution, pore size, morphology and surface chemistry of micro- an

198 rgdorferi is able to penetrate matrices with pore sizes much smaller than the diameter of the bacteri

199 that contained two discrete distributions of pore sizes: nanopores and macropores.

200 ut steric restriction, which calculates to a pore size of >140 nm in diameter.

201 6% recovery of the spiked plasmid DNA with a pore size of 0.2 mum.

202 erage particle size of 290mum and an average pore size of 14.3mum, providing a micro-carrier for the

203 -assembled collagen networks with an average pore size of 3 mum.

204 n of nanosized MIL-101(Cr), with the largest pore size of 3.4 nm, led to an exceptional increase in p

205 In contrast, the calculated pore size of a brain metastasis of breast cancer was app

206 Nanoporous mannitol with a mean pore size of about 6 nm exhibited 0.24-fold carrier dens

207 ed radially oriented mesochannels, and large pore size of approximately 11 nm.

208 he poly(ether sulfone) membrane with average pore size of approximately 350 nm.

209 le surface area of 619 m(2) g(-1), and large pore size of approximately 8 nm can be fabricated by sub

210 The pore size of biopolymer networks governs their mechanica

211 h very small nanoparticles (smaller than the pore size of DGT samplers) can be abundant in certain en

212 nt on the volume of narrow micropores with a pore size of less than 0.8 nm rather than the volume of

213 rks (ZIFs) are challenging, due to the small pore size of materials such as ZIF-8 and the wide range

214 proaches have been attempted to increase the pore size of MOF materials, it is still a challenge to c

215 tural molecular modeling predicted a reduced pore size of mutant NMDARs.

216 on process has been developed to control the pore size of ordered mesoporous silica materials in a st

217 ntly loaded with DNR by engineering the nano-pore size of pSi.

218 C channels and found that 2-APB enlarged the pore size of STIM1-activated Orai1 from 3.8 to 4.6 A.

219 e attributed to the smooth surface and small pore size of the biocompatible PPy coating, which was pr

220 of three types of inclusion depending on the pore size of the framework: single-molecule confinement

221 o retain particles that are smaller than the pore size of the gill-raker filter, including extraction

222 e dependent cut-off filter adjustable by the pore size of the hydrogel.

223 have hydrodynamic diameters smaller than the pore size of the membrane is due to the zwitter ionicall

224 The pore size of the MONTs is adjusted by changing the centr

225 ed by a single parameter--the characteristic pore size of the network.

226 investigated the feasibility of altering the pore size of the silicon particles to regulate the paylo

227 ce for water vapor increases with increasing pore size of the zeolite (in case of zeolite 5A, all oth

228 A nanoporous gold film with pore size of ~20 nm was prepared by a metallic corrosion

229 ogel with a Ferguson plot yields an apparent pore size of ~31 nm.

230 senting the fraction of the pore volume with pore sizes of less than 10-20 mum is inversely related,

231 ibiting hyper-permeability and enlarged open-pore sizes of the fenestrated endothelium and loss of VE

232 Our data reveal that smaller pore sizes offer stronger interactions, as determined by

233 We evaluated the role of soil aggregate pore size on biodegradation of essentially insoluble pet

234 D channels facilitate study of the impact of pore size on gas sorption parameters in situations where

235 In this study, the influence of pore size on regeneration by Fenton oxidation for carbon

236 ks to open-lattice crystals, the latter with pore sizes on the order of tens of nanometres, that is,

237 Aspects such as pore size or stiffness of the matrix influence the selec

238 allowing conclusions to be drawn on apparent pore sizes, or suggesting functional properties such as

239 composed of isoelectric focusing in a large pore-size polyacrylamide gel to determine protein pI fol

240 The key parameters are shown to be the pore size, pore angle, mesh rotation, tilt angle (branch

241 io, it is possible to tune the surface area, pore size, pore anisotropy, and dimensions of titania cr

242 which ultimately allow for tailoring of the pore size, pore shape, and/or properties towards specifi

243 These MOFs exhibit similar pore size, pore surface, and surface area (around 3000 m

244 The pore size, pore throat size and coordination number obey

245 r the best future mesoporous materials (e.g. pore sizes, pore connectivity, shape, surface chemistry)

246 The effect of AG on the pore-size, porosity, surface morphology, surface charge,

247 substantially higher than those with similar pore size prepared by conventional phase-separation proc

248 analysis of experimental porosimetry data, a pore size probability density function is introduced to

249 ost-injection day 14 was 66.52ng/mL for 95nm pore size pSiO2-CO2H:DNR, 10.76ng/mL for 43nm pSiO2-CO2H

250 micro-CT imaging porosity (R(2) = 0.79) and pore size (R(2) = 0.81); age (R(2) = 0.64); peripheral q

251 esoporous-classified pores at the sub-100 nm pore size range investigated.

252 ns the same fluoranthene core, the resultant pore sizes range from microporous (10 A) to mesoporous (

253 ncrease linearly with etching time where the pore size ranged from 4 to 12 nm with corresponding poro

254 ore specifically three carbon supports, with pore sizes ranging from mainly microporous to half micro

255 103, each exhibit permanent mesoporosity and pore sizes ranging from ~2.1-2.9 nm and surface areas ra

256 igate the effects of applied stress and cell/pore-size ratio on mechanotype measurements.

257 taining hierarchical networks of pores, with pore size ratios that have evolved to maximize mass tran

258 also find that Ea increases for larger cell/pore-size ratios, even when the same applied stress is m

259 of 30 nm were uniformly distributed and the pore size reduced to 24 nm and 18 nm during subsequent e

260 The larger pore size reduces shear viscosity (by approximately 70%)

261 orption properties of MONTs as a function of pore size revealed selective uptake of CO2 and CH4, with

262 f metal hydration, which correlates with the pore size/rigidity as well as the composition and solven

263 ental insights into the relationship between pore size/shape and host-guest interactions.

264 roximately r(4), the layer with the smallest pore size should be as thin as possible.

265 nanopore thin films, which are optimized for pore size, structure, capillary force, and film thicknes

266 several cations but not the estimated AMPAR pore size, suggesting that TARP-induced relief of polyam

267 ighest signal for the low-porosity and small-pore-size surfaces.

268 Type I double-helix hydrogel exhibits larger pore sizes than type II triple-helix gel.

269 obtain arrayed multi-nanochannels with mean pore sizes that are comparable to the thickness of an el

270 vary by up to five orders of magnitude, with pore sizes that range from 4 to 350 nm.

271 Despite the relatively large pore sizes, the complete orientational randomization of

272 Despite the relatively large pore sizes, the measurements reveal that the reorientati

273 Due to the small pore sizes, the particles are only modified on their sur

274 e on polymer molecular weight as well as the pore size; the rejection increased with both increasing

275 highly uniform pore distribution and tunable pore size, these materials have been prospected as promi

276 The significant characteristics such as pore size, thickness, and porosity make the porous silic

277 ferent electrolyte composition and effective pore size to elucidate their influence on separation mec

278 ssover is arrested by scaling the membrane's pore size to molecular dimensions and in turn increasing

279 el is presented that incorporates a range of pore sizes to more accurately predict the capillary tran

280 interface (ALI) on the underside of 3 microm pore-sized transwells, compatible with the study of tran

281 Pore size tunability between 500 nm-10 microm is establi

282 rpore (polymer solvodynamic size relative to pore size) values as low as 0.3.

283 l recovers the classical mean model when the pore size variance is very small.

284 gh surface area and tunable primary particle/pore size via a self-templating pore formation process.

285 e size distributions became broader when the pore size was increased and featured two distinct peaks.

286 The phase evolution as a function of pore size was investigated by X-ray diffraction, IR, the

287 These data showed that pore size was the governing factor in cell viability, in

288 ne fluoride (PVDF) membrane of 40 nm nominal pore size was used to study bacteriophage MS2 removal un

289 mns packed with material possessing a larger pore size, was used.

290 extend in-gel immunoprobing to gels of small pore size, we describe an optional gel de-cross-linking

291 ble activities with intracellular uptake and pore size, we designed a ramped pulse exposure scheme fo

292 To determine the bioaccessible pore sizes, we performed separate experiments to assess

293 Its pore sizes were divided into five regions based on nanop

294 rom different dialysis settings and membrane pore sizes were used to substantiate this approach.

295 raphene frameworks with vast distribution of pore sizes, which maximizes the active-sites accessibili

296 n the wildtype (WT) Orai1 channels of narrow pore sizes, while conducted decreased or no Ip on Orai1-

297 provide reproducible control over nanoscale pore sizes with an atomic level of precision.

298 ceramic microfiltration membranes (0.22 mum pore size) with cysteic acid creates a superhydrophilic

299 The average pore size xi0 of filamentous networks assembled from bio

300 e we provide a new strategy for hierarchical pore size zeolite synthesis, without using supramolecula