ライフサイエンスコーパス: fractionation

1 onation and 2,591 (60.7%) after conventional fractionation.

2 ences existed according to radiotherapy dose fractionation.

3 cific isotope analysis (CSIA) and enantiomer fractionation.

4 model was also used to investigate treatment fractionation.

5 the expected enrichment based upon classical fractionation.

6 rongly affected the direction of Zn isotopic fractionation.

7 tify the global flux and associated isotopic fractionation.

8 een shown to be non-inferior to conventional fractionation.

9 putum optimization involved liquefaction and fractionation.

10 e has undergone a substantial post-polyploid fractionation.

11 onation and 1,165 (27.3%) after conventional fractionation.

12 was accompanied by a ca. 1 per mille isotope fractionation.

13 reservoir, via closed system (Raleigh-type) fractionation.

14 ntent and saturate-aromatic-resin-asphaltene fractionation.

15 te the advantages of FAIMS-enabled gas-phase fractionation.

16 ,951 (45.7%) of those receiving conventional fractionation.

17 mille, presumably due to post-photosynthetic fractionations.

18 ransitioning wavefronts patterns and complex fractionations.

19 ometry approaches address by two-dimensional fractionation (2D) to reduce sample complexity during da

20 We found high pH reversed-phase fractionation a useful tool to increase assay sensitivit

21 Fickian and Nernst-Planck diffusion, isotope fractionation, advection-dispersion transport, and rock-

22 r analysis (BET), Asymmetric Flow Field-Flow Fractionation (AF4) and in vitro cell viability measurem

23 In this study, an asymmetric flow-field flow fractionation (AF4) system coupled with UV and MALS dete

24 nline coupling of asymmetric flow field-flow fractionation (AF4) with inductively coupled plasma-tand

25 T1, by coupling Asymmetrical Flow Field-Flow Fractionation (AF4) with Systematic Evolution of Ligands

26 findings, paired with observed differential fractionation along formulas nitrogen and oxygen content

27 Using subcellular fractionation, an improved sequence database and MS we d

28 Subcellular fractionation analyses revealed that SYNV sc4 and TYMaV

29 Subcellular fractionation analysis using OptiPrep density gradient c

30 ated region (UTR), as determined by polysome fractionation and 5'UTR-reporter assays.

31 integrating large scale proteomics, polysome fractionation and a focused RNAi approach that Nup155 co

32 evaluated using bottom-up MS with the aid of fractionation and a multi-step peptide search strategy t

33 analyzing >16,000 predominantly metazoan co-fractionation and affinity-purification mass spectrometr

34 fractionation (FlFFF) with ICP-MS/MS for the fractionation and analysis of natural nanoparticles (NPs

35 Samples were extracted without cleanup/fractionation and analyzed using targeted and nontargete

36 les, we have developed the nanoFAC (nanoflow Fractionation and Automated Concatenation) 2D RPLC platf

37 Using cell fractionation and cell contact-dependent assay, we made

38 The association of LGE with electrogram fractionation and delay remains to be examined.

39 bservations from high resolution biochemical fractionation and electron microscopy, coupled with anal

40 hlorocyclohexane (alpha-HCH), showed isotope fractionation and enantiomer fractionation during biodeg

41 chromatography (LC/LC) for extensive peptide fractionation and high-resolution tandem mass spectromet

42 Subcellular fractionation and immunoblot analysis revealed that ATP

43 Fractionation and merging of muscle synergies may be a m

44 -11.5 per mille, consistent with biological fractionation and mostly within a restricted range incon

45 m high-throughput methods utilising cellular fractionation and proteomic profiling.

46 Using biochemical fractionation and proteomics, we found that Ambra1 binds

47 Furthermore, fractionation and proximity-ligation assays reveal that

48 nalytical approach, the samples did not need fractionation and purification, which is typically used

49 is challenge, we applied a novel biochemical fractionation and quantitative proteomic approach to exa

50 Using subcellular fractionation and quantitative proteomics, we produced a

51 vity comparable to, if not better than, deep fractionation and requires minimal total sample input (~

52 Using nuclear/cytoplasmic fractionation and RNA in-situ hybridization assays, we d

53 rove protein quantitation, we optimized cell fractionation and sample processing steps at both the pr

54 Subcellular ER fractionation and subsequent limited proteolytic treatme

55 ecific spectrum libraries, requiring offline fractionation and tens to hundreds of injections.

56 E, with the caveats that post-photosynthetic fractionations and intrinsic variability of g(m) should

57 n immunopreciptation sequencing, subcellular fractionation, and atomic absorbance spectroscopy] and r

58 C1, and RHOA were measured with G-LISA, cell fractionation, and immunoblots.

59 re, using cavin-1 knockout mice, subcellular fractionation, and immunoblotting methods, we addressed

60 orescence staining, immunoblots, subcellular fractionation, and immunoprecipitation experiments.

61 genome-wide expression dominance and biased fractionation, and lead to a new level of understanding

62 emonstrate a strong effect of TBI dose, dose fractionation, and risk of SMNs after HCT.

63 as undetectable by microscopy or subcellular fractionation, and this pool was estimated to be <200 mo

64 r oxidative conditions, possibly without any fractionation, and transported outside the NRZs.

65 A biotin pulse-chase/subcellular fractionation approach to examine ribosome exchange at t

66 ssion X-ray microscopy) with a density-based fractionation approach to physically and microscopically

67 tforward way without any prior enrichment or fractionation approaches.

68 Changes in the lipid/water fractionation are also strongly correlated with the type

69 tabolic flux analysis to show that (2)H/(1)H fractionations are highly correlated with fluxes through

70 rtant implications for the use of Hg isotope fractionation as a tracer of the Hg biogeochemical cycle

71 First, we describe PreOmics fractionation as an effective 2D offline strategy.

72 at may have implications for uranium isotope fractionation as well as for the molecular-scale underst

73 dicines, we developed a bioactivity-directed fractionation assay for nectar metabolites.

74 maging analysis and SNAP-tag sucrose density fractionation assays revealed the dual glycosylation mut

75 ting past pCO(2), the stable carbon isotopic fractionation associated with photosynthesis (E(p)) has

76 Here, we investigated the carbon isotope fractionation associated with the oxidation of benzene a

77 ms might modulate the observable HCH isotope fractionation at contaminated sites.

78 processes such as metal-silicate Si isotope fractionation at reduced nebular environment and vapor l

79 important potential for contrasting isotopic fractionation at the diel scale.

80 roteins with dextran or glucose, followed by fractionation based on size and solubility.

81 onsensus on the true equilibrium (18)O/(16)O fractionation between calcite and water ((18)alpha(cc/w)

82 Here, using cellular fractionation, biochemical analyses, and histological as

83 It is based on cellular lysate fractionation by density gradient ultracentrifugation an

84 t reaction mechanisms and masking of isotope fractionation by either limited intracellular mass trans

85 Cell lysis and proteoform pre-fractionation by gel-eluted liquid fractionation entrapm

86 The differences in isotope fractionation can be used to elucidate the contribution

87 hromatography (GPC), crystallization elution fractionation (CEF), high temperature liquid chromatogra

88 orescence, immunoblotting, RNAi, subcellular fractionation, co-immunoprecipitation assays, and CRISPR

89 Here we use sucrose gradient fractionation combined with quantitative proteomics to s

90 We report continuous fractionation conditions for length-based iDEP migration

91 Subcellular fractionation confirmed that human tau is highly enriche

92 scattering, electron microscopy, field flow fractionation coupled to online sizing detectors, centri

93 Asymmetrical flow field-flow fractionation coupled with inductively coupled plasma ma

94 Field flow fractionation coupled with inductively coupled plasma ma

95 Here, we utilized subcellular fractionation coupled with tandem mass spectrometry and

96 ial, showing that 24 Gy SDRT, but not 3x9 Gy fractionation, coupled early tumor ischemia/reperfusion

97 ble execution of 10 sequential isolation and fractionation cycles (37-80 min per cycle) with minimal

98 Further thymocyte fractionation demonstrated that DN1 and DN2, but not DN3

99 The processes governing the Hg isotopic fractionation differ across sites depending on mixing, t

100 This masking of isotope fractionation directly evidenced mass transfer limitatio

101 trace concentrations, the absence of isotope fractionation does not necessarily indicate the absence

102 (13)C in the top microbial mat layer show no fractionation due to non-discriminating photosynthetic f

103 g different organic materials due to isotope fractionation during biochemical synthesis and degradati

104 showed isotope fractionation and enantiomer fractionation during biodegradation.

105 on the output flux of magnesium and isotopic fractionation during low-temperature ridge flank hydroth

106 Thus, the kinetic isotope fractionation during microbial degradation and the prefe

107 Silicon isotope fractionation during sinter precipitation (i.e. Delta(30

108 Here, we describe Hg isotope fractionation during the abiotic dark oxidation of disso

109 ct of U(VI) reduction kinetics on U isotopic fractionation during U(VI) reduction by a novel Shewanel

110 ood, we experimentally determined N-isotopic fractionations during metal-silicate partitioning (analo

111 trostatically embedded generalized molecular fractionation (EE-GMF) method, a method based on the sys

112 ive understanding of non-equilibrium isotope fractionation effects instead of relying on phenomenolog

113 ons were within the range of natural isotope fractionation effects.

114 biodegradation often result in enantiomeric fractionation (EFr), i.e., the change of the relative ab

115 oform pre-fractionation by gel-eluted liquid fractionation entrapment electrophoresis are then descri

116 Despite variable single element isotope fractionation (epsilon(C) = -5.0 to -19.7 per mille; eps

117 ere, we measured the stable chlorine isotope fractionation (epsilon(Cl)) associated with the major ab

118 l radicals, whereas a large chlorine isotope fractionation (epsilon(Cl)) of -10.9 +/- 0.7 per mille (

119 the systematic controls on the magnitude of fractionation (epsilon) are known.

120 s, atrial LGE is associated with electrogram fractionation even in the absence of voltage abnormaliti

121 Polysome fractionation experiments confirmed eIF4E could modulate

122 In the latter case, cell fractionation experiments displayed that mitochondrial m

123 Extensive RNA FISH and fractionation experiments established that NORAD localiz

124 rived from a comprehensive series of isotope fractionation experiments with numerous Fe(II)-bearing m

125 roscopy, fluorescence spectroscopy, and cell fractionation experiments, we found that depending on th

126 Secondary and tertiary fractionations exploited differences in selectivity acro

127 isotope ratios is set by the triple isotope fractionation exponent theta that can be determined prec

128 dehydration, suggesting a positive H isotope fractionation factor between minerals and H(2)-bearing f

129 gnesium from the ocean, with a flux-weighted fractionation factor of ~0.9994 acting to increase the m

130 t 33 backbone amides from hydrogen/deuterium fractionation factors by nuclear magnetic resonance spec

131 icle separation/characterization (field-flow fractionation (FFF), UV, and multiangle light scattering

132 of the particulate material retained by the fractionation filters revealed that Pb was dominantly pr

133 After ultrafiltration and chromatographic fractionation, five potent ACEi peptides, VRP, LKY, VRY,

134 Here, flow field-flow fractionation (FlFFF) combined with offline EEM measurem

135 The coupling of flow field flow fractionation (FlFFF) with ICP-MS/MS for the fractionati

136 on of milk fat was isolated via dry, thermal fractionation, followed by a solvent washing process.

137 air reaction, are isolated by cell lysis and fractionation, followed by immunoprecipitation with dama

138 al phenolics and o-diphenols quantified from fractionation (fraction 1, vacuolar tannins; fraction 2,

139 fferential centrifugation & density-gradient fractionation from bronchoalveolar lavage fluid (BALF) i

140 ich consists of juice extraction by physical fractionation from plant material and recovery of its ch

141 Immunocytochemistry and subcellular fractionation gave consistent results demonstrating nucl

142 sional electrophoresis (2D-PAGE) for protein fractionation, graphite furnace atomic absorption spectr

143 tions and/or high respiration rates, whereas fractionations greater than that of Apr require a low ch

144 for the low-temperature hydrothermal isotope fractionation has hindered this approach.

145 ty chromatography-asymmetric flow field-flow fractionation (IAC-AsFlFFF).

146 ore, this work proposal sought to obtain the fractionation, identification and study of mercury - bou

147 Here, using subcellular fractionation, immunoblotting and fluorescence, siRNA-ba

148 s to the myofilament compartment as shown by fractionation, immunofluorescence, and proximity ligatio

149 Detailed cell fractionation, immunoprecipitation, microscopy, and immu

150 antle wedge caused no significant Si isotope fractionation, implying closed system conditions, serpen

151 present a detailed study of sulphur isotope fractionation in a Mesoproterozoic alkaline province in

152 Here we performed nuclear-cytoplasmic fractionation in a mouse endothelial cell line and chara

153 ir-derived N(2) that experienced (15)N/(14)N fractionation in hydrothermal systems.

154 al to allow us to resolve different modes of fractionation in industrial and natural processes.

155 adation processes do, however, cause isotope fractionation in methyl halides after emission and hence

156 at CO(2) exerts a strong control on isotopic fractionation in natural phytoplankton communities.

157 st, compost OM composition was determined by fractionation in operationally defined humic, fulvic, an

158 chanisms determine the extent of PCE isotope fractionation in the Desulfitobacterium genus.

159 ossible mechanisms contributing to deuterium fractionation in the interstellar medium.

160 with slowed conduction, greater electrogram fractionation, increased fibrosis, and lateralization of

161 rison with a flow injection analysis without fractionation, ion suppression decreased from 89% to 25%

162 ental data, we show that molybdenum isotopic fractionation is driven by preference of heavier Mo isot

163 This fractionation is driven by the underlying stochasticity

164 Enzymatic fractionation is expressed as an epsilon value, and is r

165 The fractionation is realized by the implementation of three

166 A primary source of this fractionation is the diversity of approaches used to red

167 n at 256 ug/mL and underwent bioassay-guided fractionation, leading to the isolation of pentagalloyl

168 Bioactivity- and mass-guided fractionation led to the pyonitrins, highly complex arom

169 and immunoelectron microscopy, and podocyte fractionation localized endogenous and transfected APOL1

170 Sub-cellular fractionation localized increased claudin 2 protein to t

171 the potential presence of volatile DBPs and fractionation losses do not allow for tentative confirma

172 By using co-fractionation mass spectrometry, we recovered known comp

173 to efficiently correct instrumental isotopic fractionation/mass bias and matrix effects.

174 U isotope fractionation may serve as an accurate proxy for U(VI) r

175 Small fractionations may be attributed to low sulfate concentr

176 multi-detector asymmetrical-flow field flow fractionation (MD-AF4) to accurately and reproducibly se

177 We observe equilibrium mass-dependent fractionation (MDF) with enrichment of heavier isotopes

178 observed during sampling, the mass dependent fractionation (MDF, delta(202)Hg) of GEM taken up by the

179 s successfully quantified from its N isotope fractionation measured in the column effluent based on t

180 was the development of an on-line extraction/fractionation method based on the coupling of pressurize

181 A 2D-liquid chromatographic fractionation method was combined with direct infusion e

182 ast strains, membrane protein extraction and fractionation methods, and in vitro binding assays, we m

183 Hg(II) and a small negative mass-independent fractionation (MIF) owing to nuclear volume effects.

184 Whereas no mass independent fractionation (MIF) was observed during sampling, the ma

185 ds to investigate potential mass-independent fractionation (MIF).

186 Using an isotopic fractionation model informed by these data, we constrain

187 lem, we have developed an automated and fast fractionation module coupled online to MS.

188 The large difference in chlorine isotope fractionation observed between tropospheric and bacteria

189 udy demonstrates that enantiomer and isotope fractionation of alpha-HCH are two independent processes

190 ial populations and combines electrophoretic fractionation of bacterial cells with automated collecti

191 Fractionation of beta-lactoglubulin (beta-lg) and alpha-

192 Fractionation of bioactive samples identified that the c

193 nisms leading to the efficient breakdown and fractionation of biomass into valuable chemical precurso

194 dwater at a field site, where carbon isotope fractionation of CFC-11 suggests naturally occurring bio

195 components were added to the Moon after the fractionation of Cl isotopes.

196 In this study, we compared the isotopic fractionation of copper in the GI tract of mice with int

197 oducts obtained from the reductive catalytic fractionation of corn stover, depleting alkylguaiacols a

198 The fractionation of crude-oil mixtures through distillation

199 the magnitude of carbon and chlorine isotope fractionation of Desulfitobacterium strains harboring th

200 We performed an unbiased bioactivity-guided fractionation of eggs of the butterfly Pieris brassicae.

201 electrophoresis is a tool for the continuous fractionation of electrically charged analytes.

202 olid phase extraction method enabled routine fractionation of Fe in red and white wines whilst the ad

203 Fractionation of grape seed macerates was achieved by li

204 en the upper and lower mantle), aided by the fractionation of lead in a mineral that is stable only i

205 r membranes demonstrated nonthermal membrane fractionation of light crude oil through a combination o

206 downregulation of FSP27beta resulted in the fractionation of lipid droplets, whereas its overexpress

207 e centered around the use of activity-guided fractionation of metabolite extracts.

208 ul optofluidic technique enabling label-free fractionation of microscopic bioparticles from heterogen

209 detectors has been optimized to perform the fractionation of natural NPs present in a gas condensate

210 CheRNAs can be identified by biochemical fractionation of nuclear RNA followed by RNA sequencing,

211 Fractionation of samples allowed the identification of b

212 nd, in some cases, the extent of evaporative fractionation of stored karst water.

213 eam radiotherapy (MRT) is based on a spatial fractionation of synchrotron X-ray microbeams at the mic

214 n delivered at AFN detected by fragmentation/fractionation of the endocardial electrograms and by 3-d

215 lay out the challenges that have led to the fractionation of the field and that continue to form obs

216 Fractionation of the iron from the digested extracts was

217 Fractionation of the Koroneiki extract identified oleuro

218 Activity-guided fractionation of the Mycetocola proteome, matrix-assiste

219 A sucrose gradient fractionation of the nuclear lysate resolved several rib

220 ycoforms directly in plasma or serum without fractionation of the samples or glycopeptide enrichment.

221 Bioassay-guided fractionation of the source extract resulted in the isol

222 the one hand, with synergies resulting from fractionation of those revealed by sporadic weight-beari

223 We report a size fractionation of titania (TiO(2)) nanoparticles absorbed

224 "what-is-where" design that allowed for the fractionation of WM recall into separate components: ide

225 isentangle the competing effects of isotopic fractionations of water during respiration in humans.

226 act of total body irradiation (TBI) dose and fractionation on risk of subsequent malignant neoplasms

227 d to delineate the effects of radiation dose fractionation on the KLF2 signaling cascade at early tim

228 m levels require either concatenated peptide fractionation or enrichment via antibody depletion, whic

229 is is accomplished without any peptide-level fractionation or enrichment.

230 eparation method without the need for sample fractionation or enrichment; instead, we utilize trypsin

231 se data clearly indicate that radiation dose fractionation plays a critical role in modulating levels

232 Using a seven-step biochemical fractionation procedure and a drop-out mass spectrometry

233 The assay applies a fractionation procedure to antibiotic-treated bacterial

234 A sequential fractionation procedure was used to determine the effect

235 nsive analysis of factors that influence the fractionation process and subsequent physical characteri

236 The fractionation process applied to make SPI did not increa

237 otein isolate obtained by a conventional wet fractionation process.

238 pic values are inconsistent with equilibrium fractionation processes and instead suggest early and ex

239 alternatively positive and negative isotope fractionation, producing the sorption of light Zn (Delta

240 This study uses reductive catalytic fractionation (RCF) in flow-through reactors as an analy

241 g disease was rare and not influenced by the fractionation regimen.

242 The large C and H isotope fractionation reported here for experiments with pure en

243 Further enrichment by repetitive HPLC fractionation resulted in the quantitation of 6 addition

244 Sulfur isotope fractionation resulting from microbial sulfate reduction

245 In vivo interactome and density fractionation reveal that Rhes coimmunoprecipitates and

246 actively translated mRNAs by sucrose cushion fractionation revealed an increased abundance of these t

247 Cell fractionation revealed temporal gene regulation, in whic

248 Water chemistry analysis and size fractionation sampling were performed at four of these h

249 g anthropogenic and biogenic end members and fractionation scenarios to estimate ethanol source contr

250 ition of conventional radiotherapy doses and fractionation schedules.

251 The fractionation scheme applied to the ambient PM(2.5) samp

252 ell sorting method (sedimentation field flow fractionation, SdFFF) and a biosensor as a detector.

253 tation mapping (AF-Nests) using the velocity fractionation software, conventional recording, and anat

254 TCR, which applies two consecutive gas phase fractionation steps for obtaining intact precursor masse

255 To this end, two subsequent fractionation steps were performed using C18 (21 fractio

256 mass tag (TMT) labeling, online and offline fractionation strategies, our optimized workflow effecti

257 Fractionation studies identified that the active compone

258 Microscopy and subcellular fractionation studies in macrophages demonstrated endoge

259 Cell fractionation studies showed that Nox1 and Nox5 but not

260 re-dependent iron oxide-water oxygen isotope fractionation, suggesting that increasing seawater delta

261 An automated on-line isolation and fractionation system including controlling software was

262 the future, R-DeeP can be extended to other fractionation techniques, such as chromatography.

263 By this fractionation, the number of features detected by LC-HRM

264 separation efficiency in thermal field-flow fractionation (ThFFF) was investigated for a polymer mod

265 Thermal field-flow fractionation (ThFFF) was used to characterize the archi

266 YDGF assay, employing SDS-PAGE-based protein fractionation to deplete high-abundant proteins and a st

267 Here we used multistep N-glycan fractionation to efficiently separate anionic and neutra

268 The ability of isotope fractionation to identify mass transfer limitations may

269 Here we use activity-guided fractionation to identify specific members of papain-lik

270 approaches they pioneered, ranging from cell fractionation to immunoprecipitation to structural biolo

271 treatments: over storage of soy flours, over fractionation to yield soy protein isolate (SPI), and ov

272 ce metal enrichments and negative delta(13)C fractionations together, we propose that, although lacki

273 in these compounds followed a mass-dependent fractionation trend (MDF; Delta(33)S <= +/-0.2 mUr).

274 ing ion-exchange resins enabling large-scale fractionation using precise iterations of analytical sca

275 evidence of life, and secular variations in fractionation values reflect changes in biogeochemical c

276 c magma differentiation, the extent of Nb/Ta fractionation varies with crustal thickness with the low

277 In contrast, increased LA electrogram fractionation was associated with SI-Z (coefficient, 0.0

278 No chlorine isotope fractionation was detected for reaction of CH(3)Cl with

279 -C-Cl moieties, the observed C and H isotope fractionation was large, typical for bimolecular elimina

280 We suggest that the observed equilibrium fractionation was likely controlled by isotope exchange

281 High-pressure fractionation was more efficient for obtaining bioactive

282 phytochemical characteristics, high-pressure fractionation was more efficient for obtaining valuable

283 On-column isotopic fractionation was observed and therefore corrected by ex

284 However, significantly attenuated isotope fractionation was observed during the initial stage of H

285 atform, in which the first dimension high-pH fractionation was performed on a 75-mum i.d.

286 arbon and hydrogen compound specific isotope fractionation was pronounced at high aqueous 2-MN concen

287 The strongest shift in fractionation was seen in phytol, and pCO(2) estimates d

288 Electrogram fractionation was significantly higher in the epicardium

289 -1000) by modified aminopropyl silica (MAPS) fractionation, we found that active BES remediation resu

290 encing, confocal microscopy, and subcellular fractionation, we identified a nuclear variant of beta1-

291 Through biochemical fractionation, we identified the histone chaperone nucle

292 meability assay in human pulmonary EC and MT fractionation, we observed that HKSA-induced barrier dis

293 c TMF seepage, while attenuation and isotope fractionation were greatest during discharge and oxidati

294 Limited Mo attenuation and isotope fractionation were observed in Fe(II)- and Mo-rich anoxi

295 larger C but substantially smaller H isotope fractionation with (13)C- and (2)H-AKIEs of 1.073 +/- 0.

296 serial size exclusion chromatography (sSEC) fractionation with 12 T FT-ICR MS for targeted top-down

297 separation method for Hp/HS oligosaccharide fractionation with cross-compatible solvent and conditio

298 cells revealed a drastic decrease in isotope fractionation with declining residual substrate concentr

299 ssisted extractions were tested, followed by fractionation with different polarity solvents.

300 ase in d-excess indicates efficient isotopic fractionation within ~200 km SW of the warm core.