ライフサイエンスコーパス: chemical analysis

1 requirements for biological samples prior to chemical analysis).

2 olyte is directly visualized via advanced 3D chemical analysis.

3 spectroscopy accompanied by detailed quantum-chemical analysis.

4 for enantiomer specific synthesis as well as chemical analysis.

5 evelopment of new techniques in all areas of chemical analysis.

6 o-dimensional NMR spectroscopy together with chemical analysis.

7 nt strain 130b that is suitable for detailed chemical analysis.

8 e (NMR) spectroscopy is a versatile tool for chemical analysis.

9 h the accuracy traditionally associated with chemical analysis.

10 pic standards for accurate quantitative food chemical analysis.

11 nd the sensory data were correlated with the chemical analysis.

12 an automated suspect screening approach for chemical analysis.

13 ion mobility is enhancing many areas of (bio)chemical analysis.

14 amples resulting in an unbiased quantitative chemical analysis.

15 tems have emerged as a powerful approach for chemical analysis.

16 tandard natural soil (LUFA 2.1) suitable for chemical analysis.

17 olumes from individual adult fruit-flies for chemical analysis.

18 applications of redox-MHD microfluidics for chemical analysis.

19 transfer efficiencies high enough for proper chemical analysis.

20 llector coupled to a microfluidic device for chemical analysis.

21 n is a crucial, yet often overlooked step in chemical analysis.

22 sometimes insurmountable problems for their chemical analysis.

23 given careful shimming schemes, even perform chemical analysis.

24 mmunologic function of PAP2 by mutational or chemical analysis.

25 e dimensions are rapidly being developed for chemical analysis.

26 cellent complement to traditional methods of chemical analysis.

27 for fabrication of microfluidic devices for chemical analysis.

28 idic device for pumping, sampling, and trace chemical analysis.

29 ical testing, spectroscopic observation, and chemical analysis.

30 ple growth and preparation to the results of chemical analysis.

31 ased vascular calcification by histology and chemical analysis.

32 eir applicability for reactive chemistry and chemical analysis.

33 ance (NMR) is an emerging tool for precision chemical analysis.

34 rred into a mass spectrometer for subsequent chemical analysis.

35 werful method for automating high-throughput chemical analysis.

36 d as a light source for optical detection in chemical analysis.

37 reliability of RRS spectroscopic methods in chemical analysis.

38 elevant for environmental fate, toxicity and chemical analysis.

39 sub-Saharan Africa, 796 (35%) of 2297 failed chemical analysis, 28 (36%) of 77 failed packaging analy

40 ountries in southeast Asia, 497 (35%) failed chemical analysis, 423 (46%) of 919 failed packaging ana

41 ligrams of iron per gram of wet tissue) with chemical analysis after MR imaging.

42 taint were selected by means of sensory and chemical analysis, after which patties with different le

43 ce spectroscopy (NMR) is a versatile tool of chemical analysis allowing one to determine structures o

44 ntless organic micropollutants, and targeted chemical analysis alone may only detect a small fraction

45 Prior to chemical analysis, an initial inspection of the artefact

46 al analysis of the same food, we performed a chemical analysis and a calculation for a representative

47 Targeted chemical analysis and AChE bioassay were performed on th

48 ion exchange treatment was employed prior to chemical analysis and algal bioassays.

49 Chemical analysis and bioactivity studies revealed that

50 Techniques that combine chemical analysis and bioassays have the potential to fa

51 lised with thiols concentrations obtained by chemical analysis and blackcurrant aroma intensities obt

52 and therefore presents inherent problems for chemical analysis and characterization.

53 Magnetic Resonance ((1)H NMR), conventional chemical analysis and chemometric elaboration were used

54 al resolution of AFM in combination with the chemical analysis and compositional imaging capabilities

55 s a rapidly emerging technique that provides chemical analysis and compositional mapping with spatial

56 d the best sensory results were submitted to chemical analysis and cooking quality of pasta.

57 raphical origin were correctly classified by chemical analysis and electronic tongue (100%), but it w

58 reciated for over a century, and advances in chemical analysis and genome sequencing continue to grea

59 itivity, accuracy, and simplicity to electro-chemical analysis and is expected to become a useful too

60 ractical platform for accurate, quantitative chemical analysis and medical diagnostics.

61 processes are widely used in small molecule chemical analysis and metabolomics for derivatization, v

62 tructure of the K15 polysaccharide, based on chemical analysis and nuclear magnetic resonance (NMR) d

63 cientific advancements in organic chemistry, chemical analysis, and purification.

64 nt labeling is widely used in biological and chemical analysis, and the drive for increased throughpu

65 dioxide (TiO2) NPs, sample preparations and chemical analysis are critical steps to meaningfully ass

66 The results of chemical analysis are discussed in terms of their effect

67 most significant changes among DBDs used for chemical analysis are in how the discharge electrodes ar

68 Therefore tissue extracts prepared for chemical analysis are not amenable to assess the combine

69 The device is capable of real-time chemical analysis at scan rates up to 48 Hz.

70 spectroscopy (TERS) is a versatile tool for chemical analysis at the nanoscale.

71 ty and genotoxicity bioassays can supplement chemical analysis-based risk assessment for contaminated

72 a correlated well with results from LC-MS/MS chemical analysis but also revealed unknown PSII-inhibit

73 ly been used as an analytic tool for routine chemical analysis, but more recently, researchers have b

74 on of substrate in solution, and to simplify chemical analysis by avoiding the difficult extraction o

75 sorption ionization was designed for in vivo chemical analysis by mass spectrometry in surgical and e

76 oupling of SERS and PSI-MS to enable on-site chemical analysis by two independent methods can potenti

77 A detailed chemical analysis by ultrahigh-performance liquid chroma

78 sion, if chemometric overfitting is avoided, chemical analysis can predict sensory qualities of food

79 echanisms by which optofluidics enhances bio/chemical analysis capabilities, including sensing and th

80 Organelle purification and chemical analysis confirmed the localization of forskoli

81 TOF-SIMS chemical analysis confirmed these heterogeneous printed

82 The chemical analysis coupled with the transmission electron

83 were significantly different (p < 0.05) and chemical analysis demonstrated an increase in the produc

84 ic substrates more attractive for single-use chemical analysis devices.

85 e fruits have been subjected to physical and chemical analysis during the fruit life cycle.

86 using UV spectrophotometry (190-400 nm) and chemical analysis (enological analysis, polyphenols, oli

87 was determined by electron spectroscopy for chemical analysis (ESCA) and X-ray absorption near-edge

88 es used as chemical sensors for point-of-use chemical analysis, especially during border security app

89 3D Nanoscale chemical analysis extracted from atom probe tomography (

90 iological endpoints may therefore complement chemical analysis for water quality assessment.

91 sumed to be impressions; however, a detailed chemical analysis has, until now, never been completed o

92 FT-IR spectroscopy and chemical analysis have allowed one to detect on the phot

93 on two different sites, allowing unambiguous chemical analysis, have remained elusive.

94 iner walls and hence has been used widely in chemical analysis, high-temperature processing, drop dyn

95 d over 100 samples of snow and meltwater for chemical analysis in 2008 and 2009 from the watershed sn

96 We here identify, through chemical analysis in combination with a series of physio

97 genome sequencing, comparative genomics, and chemical analysis in four plant-associated enterobacteri

98 Rapid, in situ, and label-free chemical analysis in microfluidic devices is highly desi

99 oxine, strict regulations enforce a detailed chemical analysis in order to characterize potentially t

100 Perspectives of the chemical analysis in the food industries are also discus

101 ometry, which became a routine technique for chemical analysis in the mid-20th century.

102 and erythromycin) have been detected through chemical analysis in the PRE sediments, but not in the S

103 Physico-chemical analysis included the identification and semi q

104 we developed a platform that integrated the chemical analysis, including identification and relative

105 a variety of methods for spatially resolved chemical analysis, including optical imaging, inserted s

106 Chemical analysis indicated that V species did not leach

107 ally, monolignol feeding and lignin-specific chemical analysis indicates the presence of archetypal l

108 zed by single-crystal X-ray crystallography, chemical analysis, infrared spectroscopy, thermogravimet

109 tectors, challenging the use of conventional chemical analysis instrumentation, which often relies up

110 Their emerging use in chemical analysis is a result of several ideal character

111 y of the device to high-throughput multiplex chemical analysis is demonstrated by colorimetric and fl

112 However, hands-on time, excluding chemical analysis, is approximately 3 d for a set of abo

113 cal imaging, materials analysis, and routine chemical analysis, it is desirable to have a toolkit of

114 subjected to comprehensive spectroscopic and chemical analysis, leading to reassignment/assignment of

115 grape berries was studied using conventional chemical analysis, Magnetic Resonance Imaging (MRI) and

116 A combinative approach for chemical analysis makes it possible to distinguish a mix

117 ensured by documented traceability, although chemical analysis may add information that is useful for

118 ed sensitivity and a wider dynamic range for chemical analysis, medical diagnostics, and in vivo mole

119 A multiresidue chemical analysis methodology, using solid phase extract

120 the U.S., using an extensive suite of target-chemical analysis methods along with a variety of biolog

121 n-chip" systems could allow high-performance chemical analysis methods to be performed in situ over d

122 most abundant chemicals identified by target chemical analysis of >100 organic micropollutants and ef

123 Chemical analysis of 2 thrombi demonstrated 99 to 147 mi

124 It was applied to the evaluation of wood chemical analysis of 736 hybrid aspen trees: wild-type c

125 utility of this ion source for comprehensive chemical analysis of a series of aromatic and halogenate

126 Initially our chemical analysis of a Streptomyces strain associated wi

127 ganic matter in urban atmospheres using the "Chemical Analysis of Aerosol Online" (CHARON) inlet.

128 hod relies on the combined use of a CHARON ("Chemical Analysis of Aerosol Online") particle inlet and

129 demonstrate that atom-by-atom structural and chemical analysis of all radiation-damage-resistant atom

130 canning probe microscopy, allowing nanoscale chemical analysis of almost any organic material under a

131 Chemical analysis of AMZ and bacteria showed that Al, P,

132 Chemical analysis of an Australian coastal marine sedime

133 Chemical analysis of an Australian marine sediment-deriv

134 Chemical analysis of archaeological artifacts provides a

135 Chemical analysis of atmospheric aerosols is an analytic

136 In this work, a more detailed chemical analysis of biofuel PM was undertaken using a c

137 nd mass spectrometry have revolutionized the chemical analysis of biological molecules, including pro

138 e amplitude modulation fluorometry assay and chemical analysis of biologically active fractions using

139 he applicability of common methods for rapid chemical analysis of biomass samples with respect to acc

140 in Puerto Rico (PR) by integrating targeted chemical analysis of both inorganic (18 trace elements)

141 By considering the chemical analysis of bronze objects within archaeologica

142 gnificantly contribute to the nondestructive chemical analysis of buried thin films and interface str

143 Chemical analysis of cell wall polysaccharides and glyco

144 al and consumer applications for the on-site chemical analysis of chocolate bloom and as an alternati

145 the sensitivity and efficacy of microfluidic chemical analysis of complex organics with relevance to

146 While chemical analysis of contaminant mixtures remains an ess

147 nd SHG microscopy for an enhanced label-free chemical analysis of crystallized structures in diseased

148 This research includes a chemical analysis of effluents discharged from three WWT

149 lication of this method to the combinatorial chemical analysis of electrode materials and electrocata

150 nterdigitated array (IDA) electrode enabling chemical analysis of electrolyzed samples directly from

151 Chemical analysis of exceptionally well-preserved colore

152 New, rapid, direct chemical analysis of extracellular matrix components obt

153 Cosmochemistry is the chemical analysis of extraterrestrial materials.

154 Here we report the chemical analysis of food residues associated with Late

155 orically required time-consuming destructive chemical analysis of fragments from herbarium specimens,

156 Chemical analysis of fruit bodies revealed that they are

157 By chemical analysis of fungal biotransformation products a

158 oring of mZVI particle injection is based on chemical analysis of groundwater and soil samples and th

159 The rapid chemical analysis of individual cells is an analytical c

160 ecome available, and when high-level quantum chemical analysis of intermolecular interactions of larg

161 oftware should be a great aid in large-scale chemical analysis of ligands binding specific targets of

162 This new approach made possible the chemical analysis of liquid collected from both types of

163 rt the development of a new strategy for the chemical analysis of live cells based on protein spheric

164 Chemical analysis of low-pH culture filtrates showed tha

165 A comparative quantum-chemical analysis of major decomposition mechanisms in p

166 Comprehensive physico-chemical analysis of Map S397 extracts confirmed the str

167 itectures which can support multidimensional chemical analysis of mass-limited samples requiring sequ

168 toelectron spectroscopy strategy for surface chemical analysis of materials.

169 Chemical analysis of membrane-bound containers such as s

170 Recent literature has begun to focus on the chemical analysis of mephedrone and related substituted

171 und to be a robust and flexible tool for the chemical analysis of metals because the sample emission

172 oscopy (NELIBS) was applied to the elemental chemical analysis of microdrops of solutions with analyt

173 Methods implemented for the chemical analysis of microfluidic droplets have been lim

174 Chemical analysis of mutant extracts enabled us to isola

175 g in the brain is employed frequently in the chemical analysis of neurological function and disease,

176 Solid state chemical analysis of pharmaceutical inhalation aerosols

177 in response to a chemical signal, and direct chemical analysis of phospholipids.

178 of phosphorylation sites in proteins through chemical analysis of phosphopeptides.

179 in planta applications by presenting in situ chemical analysis of plant cell wall components, epicuti

180 ools that provide noninvasive structural and chemical analysis of plant tissues at the cellular scale

181 olecules for biomedical applications and the chemical analysis of polymers.

182 The chemical analysis of precisely dated tree rings, called

183 the structural characterization and quantum chemical analysis of proposed intermediate species.

184 a novel method of disease detection based on chemical analysis of released volatile organic compounds

185 The chemical analysis of salicylic acid, jasmonic acid, indo

186 We report a chemical analysis of Se in Brassica seeds (canola, India

187 imate community drug consumption through the chemical analysis of sewage biomarkers of illicit drugs.

188 ave enabled the high-throughput, multiplexed chemical analysis of single cells, capable of resolving

189 However, the quantitative chemical analysis of single-cell lysates remains difficu

190 Chemical analysis of small extracellular vesicles (sEVs)

191 red microspectroscopy is widely used for the chemical analysis of small samples.

192 y desorption electrospray ionization enables chemical analysis of small volumes and concentrations of

193 oxy for broad spectrum solar irradiance, the chemical analysis of spores and pollen offers unpreceden

194 Crystal chemical analysis of structures presented here and known

195 The structural and chemical analysis of synthesized nanocomposites was cond

196 mass spectrometry (NIR-LDI-AMS) was used for chemical analysis of the aerosol.

197 Chemical analysis of the bacterial volatile emissions re

198 Chemical analysis of the biofilm matrix shows that the c

199 DNA sequence comparison and chemical analysis of the cell wall identified adr as the

200 Structural and chemical analysis of the channel combined with temperatu

201 Herein, synthesis methods and details of the chemical analysis of the compounds in this series are de

202 Chemical analysis of the estrogenic samples indicated 2

203 Chemical analysis of the fecal extract of B. germanica r

204 eyond the scope of the present work, quantum chemical analysis of the fragments' interactions and can

205 eported, this work is the most comprehensive chemical analysis of the isolated noble metal phase to d

206 opanoid pathway via the characterization and chemical analysis of the metabolites in the p-coumaryl,

207 capacity of GCxGC-ToFMS allows for in-depth chemical analysis of the molecular composition.

208 M, which gives a comprehensive, quantitative chemical analysis of the monolith at a spatial resolutio

209 Biophysical and chemical analysis of the nitrite-deoxyhemoglobin reactio

210 Full chemical analysis of the O-antigens of these strains ide

211 Chemical analysis of the particles shows the presence of

212 Chemical analysis of the resistant isolates showed decre

213 Chemical analysis of the resulting tar showed typical ma

214 Chemical analysis of the resuspended PM indicated a tota

215 lated values with the values obtained from a chemical analysis of the same food, we performed a chemi

216 ial human errors, simplifying the subsequent chemical analysis of the sample.

217 eby alleviating the need for a comprehensive chemical analysis of the sample.

218 tance from the sample surface, and (3) local chemical analysis of the solid surface by confocal Raman

219 Chemical analysis of the test atmosphere and liquid reve

220 Chemical analysis of the wild-type and mutant strains en

221 While the chemical analysis of these particles is considered manda

222 etect residues in urines and only the direct chemical analysis of urine samples confirmed both beta-a

223 at residency of euryhaline elasmobranchs via chemical analysis of vertebrae.

224 tem will have application to high-throughput chemical analysis on a nanoliter scale by enabling sever

225 bility of the method to provide quantitative chemical analysis on known lipid mixtures.

226 Quantum chemical analysis on several therapeutically important g

227 ctrometers is the ability to perform in situ chemical analysis on target samples in their native stat

228 Quantum chemical analysis on the imidazole, oxazole, and thiazol

229 lavour was studied by sensory evaluation and chemical analysis (organic acids, mannitol, phenolic com

230 prehensive analysis of PCS, termed PA physio-chemical analysis (PAPCA), can lead to very rich diagnos

231 Chemical analysis performed herein reveals nonspecific m

232 Surface sampling for chemical analysis plays a vital role in applications lik

233 values for the reference fetus derived from chemical analysis previously.

234 Chemical analysis reported here reveals that bus-2 is in

235 Chemical analysis revealed a dramatic reduction of arabi

236 The chemical analysis revealed statistically different conce

237 Chemical analysis revealed that ethyl isothiocyanate (EI

238 Chemical analysis revealed that the extract was composed

239 g of 5S rRNA to its functional form and with chemical analysis revealing seven post-transcriptional r

240 absorption fine structure spectroscopy, and chemical analysis reveals that Tc(IV) replaces Fe(III) i

241 can be manually sorted out and verified with chemical analysis, sample preparation for smaller microp

242 Bulk chemical analysis, scanning electron microscopy, seconda

243 ituations selected to illustrate challenging chemical analysis scenarios.

244 e current study utilised a bioassay-directed chemical analysis scheme to screen the anti-inflammatory

245 Chemical analysis showed chia is a source of protein (19

246 Chemical analysis showed the Cabernet Sauvignon used in

247 ighly consistent with the measured levels by chemical analysis, showing a significant correlation (r(

248 However, challenges in their chemical analysis, sometimes at trace levels, and unders

249 ition were investigated during retting using chemical analysis, specific glycanase degradation and im

250 Uncertainty has been evaluated for sampling, chemical analysis, stability of drug biomarkers in sewag

251 Basic winemaking parameters and some key chemical analysis, such as concentration of glycerol, bi

252 ctivity studies, in combination with quantum chemical analysis, suggest that the two carbon atoms of

253 ioning as a specific, rather than a general, chemical analysis system.

254 n one of the major challenges of micro total chemical analysis systems for the past 15 years.

255 he first of a new generation of microfluidic chemical analysis systems with sufficient analytical per

256 ic networks suitable for use in miniaturized chemical analysis systems.

257 Recent advances in material science, chemical analysis techniques, device designs, and assemb

258 trast to alternative approaches to nanoscale chemical analysis, TERS is label free, is non-destructiv

259 ify by mutagenesis, structural modeling, and chemical analysis the unexpected catalytic participation

260 From chemical analysis, there are 0.25 g of phospholipids and

261 ytical tools can be applied complementary to chemical analysis to detect the effects of complex chemi

262 used behavioral observations, bioassays and chemical analysis to determine how males maintain their

263 bined solid-state (13)C NMR spectroscopy and chemical analysis to examine the SOM in a Japanese cedar

264 otential for stable isotope ratio as well as chemical analysis to find indications for fraud or spoil

265 reaction for sampling, dissolution, and (bio)chemical analysis to monitor their progress.

266 that combine sophisticated histological and chemical analysis to precisely sample tooth layers that

267 nic X-ray Photoelectron Spectroscopy and wet chemical analysis to study sulfur oxidation products dur

268 We have performed a high-level quantum chemical analysis to study the chromophore-protein inter

269 loy an ultrasensitive three-dimensional (3D) chemical analysis to uncover the dynamic formation of in

270 embryo toxicity test were applied along with chemical analysis to water extracts from the Danube Rive

271 ivariate statistics can be employed to guide chemical analysis, to improve de-replication, and to ide

272 g a rotating drum impactor (RDI) and organic chemical analysis using direct liquid extraction surface

273 ffer tremendous opportunities for biological/chemical analysis using extremely small sample volumes.

274 In combination with imaging and chemical analysis using high-resolution transmission ele

275 data opens significant prospects for mobile chemical analysis using NMR.

276 sed in terms of unit, mode of expression and chemical analysis, using information in national food co

277 "pseudolaratriene." Combined NMR and quantum chemical analysis verified the structure of pseudolaratr

278 Explicit chemical analysis was accomplished by introducing the GC

279 ng pressure differences, high sensitivity in chemical analysis was also achieved, with limits of dete

280 To achieve signal statistics, the chemical analysis was carried out with a sequence of sto

281 Chemical analysis was performed by SDS-PAGE and mass spe

282 Furthermore, a high-level quantum chemical analysis was performed to analyze contributions

283 sory analysis, consumer testing and detailed chemical analysis was used to better define the relation

284 Chemical analysis was used to obtain information about t

285 Furthermore, through a detailed quantum chemical analysis, we demonstrate that the electrocycliz

286 Combining bioassays, spectroscopy, and wet-chemical analysis, we found that oxidative activity in s

287 Using MS and chemical analysis, we identified marked changes of inter

288 By carrying out a surface chemical analysis, we show that through exposure to ambi

289 hemical fractionation and bioactivity-guided chemical analysis were used to identify the bio-active e

290 the importance of using both biological and chemical analysis when assessing new treatment technolog

291 mpared by using averaged root mean square to chemical analysis, which was used as the reference stand

292 ure and ruggedized pumping system, it allows chemical analysis while the instrument is being carried.

293 ional devices and systems for biological and chemical analysis with better sensitivity and specificit

294 resolution, which can be ionized for further chemical analysis with MS.

295 ts emphasize the importance of complementing chemical analysis with untargeted bioassays to help focu

296 Our approach combines surface chemical analysis with X-ray photoelectron and Auger ele

297 Chemical analysis with X-ray photoelectron spectroscopy

298 Subsequent chemical analysis within each microchannel, achieved via

299 resulting solids were characterized by bulk chemical analysis, X-ray diffraction, scanning electron

300 Chemical analysis yielded data on the content of reducin